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UNIVERSIDADE ESTADUAL DE CAMPINAS
INSTITUTO DE BIOLOGIA
Natália Matos de Menezes
FILOGEOGRAFIA DE CORAIS ESCLERACTÍNEOS NA COSTA DO BRASIL
PHYLOGEOGRAPHY OF BRAZILIAN SCLERACTINIAN CORALS
CAMPINAS
2018
Natália Matos de Menezes
FILOGEOGRAFIA DE CORAIS ESCLERACTÍNEOS NA COSTA DO BRASIL
PHYLOGEOGRAPHY OF BRAZILIAN SCLERACTINIAN CORALS
Tese apresentada ao Instituto de Biologia da Universidade Estadual de Campinas como parte dos requisitos exigidos para a obtenção do Título de Doutora em Ecologia.
Thesis presented to the Institute of Biology of the University of Campinas in partial fulfillment of the requirements for the degree of Doctor in Ecology
Orientador: Profa. Dra. Vera Nisaka Solferini
CAMPINAS
2018
ESTE ARQUIVO DIGITAL
CORRESPONDE À VERSÃO FINAL DA
TESE DEFENDIDA PELA ALUNA
NATÁLIA MATOS DE MENEZES E
ORIENTADA PELA PROF. DRA. VERA
NISAKA SOLFERINI.
Campinas, 25 de abril de 2018
COMISSÃO EXAMINADORA
- Profa. Dra. Vera Nisaka Solferini
- Profa. Dra. Mariana Freitas Nery
- Dra. Juliana José
- Prof. Dr. Sérgio Nascimento Stampar
- Profa. Dra. Sónia Cristina da Silva Andrade
Os membros da Comissão Examinadora acima assinaram a Ata de Defesa, que se
encontra no processo de vida acadêmica do aluno.
“Mar, metade da minha alma é feita de maresia
Pois é pela mesma inquietação e nostalgia,
Que há no vasto clamor da maré cheia,
Que nunca nenhum bem me satisfez.
E é porque as suas ondas desfeitas pela areia
Mais fortes se levantam outra vez,
Que após cada queda caminho para a vida,
Por uma nova ilusão entontecida.
...”
Sophia Andresen
AGRADECIMENTOS
Agradeço à Coordenação de Aperfeiçoamento de Pessoal de Nível Superior
(CAPES) pelo financiamento necessário para a realização desta tese entre março de
2013 e março de 2017;
À Pós-graduação em Ecologia da Unicamp, aos professores pela contribuição
na minha formação em ecologia e aos funcionários da secretaria por resolverem as
questões administrativos sempre com muita disposição;
À minha orientadora Dra. Vera Solferini por aceitar o desafio de me orientar
em uma área em que eu não tinha experiência prévia. Essa decisão me permitiu
ampliar a minha área de atuação e ter contato com novas visões dentro da Biologia.
Agradeço por me ajudar nesta empreitada, por acreditar no trabalho, pelos
incentivos. Agradeço também pelos bons e enriquecedores momentos extra
acadêmicos.
À Técnica do laboratório, Célia Bresil, pela paciência em me apresentar a
rotina do laboratório, por estar junto e disposta a ajudar em todas as fases das
atividades de bancada e por não deixar faltar aquele famoso cafezinho, essencial
para manter a energia e empolgação no dia a dia;
Ao Prof. Dr. Márcio José da Silva pelo sequenciamento das amostras no
Laboratório de Biologia Molecular de Plantas (CBMEG) e pela simpatia;
Ao Prof. Dr. José Roberto Trigo por me permitir usar equipamentos de
fotografia do seu laboratório (Laboratório de Ecologia Química - UNICAMP).
Aos amigos de laboratório, Elen Peres, Fernanda Fontes, Cecília Fiorini, Jair
Mendes, Luiz Bartoleti, Thadeu Sobral – Souza, Priscila Madi, Felipe Roberto,
Beatriz Pereira, Lívia Zuffo, Gustavo Pugliese, Wendy Arroyo, João Claudio. Sem
sua ajuda, companheirismo, conselhos, conversas e momentos de descontração, eu
não conseguiria ter feito metade do trabalho;
Ao Prof. Dr. Ruy K. P. Kikuchi (Laboratório de Estudos de Recifes de Corais e
Mudanças Globais - Universidade Federal da Bahia), por financiar as atividades de
campo realizadas no Arquipélago Tinharé – Boipeba e na região de Abrolhos;
Ao Prof. Dr. Kenneth Johnson (Natural History Museum, London) por ajudar
com informações sobre fósseis dos corais estudados.
À Profa. Dra. Liana Mendes e sua aluna Msc. Aline Medeiros (Universidade
Federal do Rio Grande do Norte) por coletarem as amostras de recifes do Rio
Grande do Norte;
À Dra. Bárbara Pinheiro (Universidade Federal de Pernambuco) por coletar as
amostras provenientes da Reserva Biológica Atol das Rocas;
À querida família Braga, gaúchos no Ceará, amigos de tantas datas e de
tantos reencontros incríveis, por me receberem durante as coletas em Fortaleza;
À toda as pessoas que me auxiliaram de diferentes formas durante as
atividades de campo, aos pescadores Everildo, ‗Cutia‘ e ‗Budião‘ pela simpatia, a
Jorge Freitas pela empolgação contagiante nos dias de trabalho (operadora de
mergulho Águas Abertas - SSA), a tripulação do catamarã Horizonte Aberto
(operadora de turismo, Caravelas - BA) por proporcionarem um ambiente alegre nos
dias embarcados, aos colegas biólogos e oceanógrafos José de Anchieta Nunes,
Ricardo Miranda, Miguel Loiola, Lua Porto, Thiago Albuquerque, Adriano Leite,
Cláudio Sampaio, José Amorim, Patrícia Ferreira, Igor Cruz, Beatriz Pereira pelos
bons momentos durante as coletas e pelas trocas de experiências;
À Profa. Dra. Elizabeth Neves, por me incentivar a realizar este trabalho.
Serei sempre grata pelo apoio. Agradeço também por me ajudar nas identificações
dos corais do gênero Siderastrea;
Aos meus pais e irmão por me incentivarem em todos os caminhos que segui
e que pretendo seguir, por me apoiarem nos momentos difíceis e por aguentarem
com serenidade a distância durante o período do doutorado;
À Igor Cruz pelo amor, por estar junto, mesmo que nem sempre fisicamente,
nos melhores e nos mais complicados momentos, por ser um grande companheiro;
Ao ‗Lapepinê‘ pelas risadas infindáveis! Porque a zueira ‗never ends‘! =D
Aos companheiros de república que tive aos longo destes quatro anos, às
meninas da Miniiecamp, à Renata, à Cecília, à Gabí, à Aline, ao Daniel, à Alê, à Lu e
à Eva pela ajuda nas questões do dia a dia e pela vivência enriquecedora. Um
agradecimento especial às três últimas pelas estadias esporádicas nesses últimos
meses em que eu já não morava em Campinas;
Aos meus amigos por continuarem me fazendo feliz!
RESUMO
Recifes de corais são importantes ecossistemas para a biodiversidade
marinha, entretanto, a sua história evolutiva tem sido pouco estudada. Os recifes
brasileiros são considerados marginais devido a distância do centro de diversidade
caribenho e às condições ambientais não ideais em que se desenvolvem. Estudos
sugerem que a sua formação atual é recente uma vez que, no Último Máximo
Glacial, o nível do mar teria descido 120 m e a plataforma continental onde ocorrem
hoje estaria exposta. Hipóteses sobre a formação da sua diversidade atual incluem
colonizações recentes a partir do Caribe ou dispersão a partir de refúgios climáticos
em montanhas submersas próximas ao banco de Abrolhos. Neste trabalho, nós
associamos abordagens filogeográficas à análises morfológicas e modelagens
paleoclimáticas para estudar processos históricos responsáveis pela distribuição
atual da diversidade de dois grupos de corais na costa do Brasil, o gênero
Siderastrea e a espécie endêmica Mussismilia braziliensis. No primeiro capítulo,
‗Phylogeography of the genus Siderastrea (Anthozoa, Scleractinia) in Southwest
Atlantic: insights about the historical formation of coral biodiversity in marginal reefs‘,
os resultados indicaram que as duas espécies do gênero encontradas no Brasil são
muito similares às congêneres S. radians e S. siderea e que a endêmica S. stellata
pode ser uma variação morfológica de S. siderea, o que mostrou a necessidade de
uma revisão taxonômica do grupo. As análises intraespecíficas de diversidade
genética, estrutura e demografia não corroboram as hipóteses de colonização
recente e indicam que as espécies parecem ter mantido a sua amplitude latitudinal
de ocorrência atual ao longo do tempo. No segundo capítulo, ‗Paleoclimatic
distribution and phylogeography of Mussismilia braziliensis, and endemic coral of
Brazilian coast‘, tanto as análises filogeográficas quanto as simulações
paleoclimáticas indicaram que a M. braziliensis também parece ter mantido a sua
distribuição latitudinal ao longo das últimas variações no nível do mar. Os resultados
para ambos os grupos sugerem que a costa do Brasil pode ter sido relativamente
estável ambientalmente no tempo geológico em relação à outras regiões no
Atlântico. Este trabalho traz importantes informações sobre os grupos estudados e
sobre a biogeografia histórica dos atuais recifes de corais brasileiros.
ABSTRACT
Coral reefs are important ecosystems for marine biodiversity, however, their
evolutionary history has been poorly studied. Brazilian coral reefs are considered
marginal due to the distance from the Caribbean center of diversity and due to the
suboptimal environmental conditions. The formation of their current reefs structures is
very recent once the continental shelf where they occurs today were exposed in the
Last Glacial Maximum. Some studies suggest colonization from the Caribe or
dispersal from refuges in submerged mountain near the Abrolhos bank. Here, we
associate phylogeographic approaches to morphological analysis and paleoclimatic
modeling to study historical processes responsible for the current distribution of the
diversity of two groups of Brazilian corals, the genus Siderastrea and the endemic
species Mussismilia braziliensis. In the first chapter, entitled ‗Phylogeography of the
genus Siderastrea (Anthozoa, Scleractinia) in Southwest Atlantic: insights about the
historical formation of coral biodiversity in marginal reefs', the results indicated that
the two Brazilian species are strictly similar to the Caribbean congeners S. radians
and S. siderea and that the endemic S. stellata seems to be a morphological
variation of S. siderea, which showed the need for a taxonomic revision of the group.
Genetic diversity, structure, and demography into both species do not corroborate the
hypotheses of recent colonizations and indicate that the species have maintained
their current latitudinal range of occurrence along geological time. In the second
chapter, entitled ‗Paleoclimatic distribution and phylogeography of Mussismilia
braziliensis, an endemic coral of Brazilian reefs‘, both, phylogeographic analyzes and
paleoclimatic simulations indicated that M. braziliensis also appears to have
maintained its current latitudinal distribution over last sea level variation. The results
for both studies suggest that the Brazilian coast remained environmentally stable
when compared to other regions in the Atlantic along the geological time. This work
presents important information on the general knowledge of the studied corals and
on the historical biogeography of the current Brazilian coral reefs.
LISTA DE TABELAS E FIGURAS
LISTA DE FIGURAS
Introdução geral
Figura 1. Imagens dos corais estudados. À esquerda, uma colônia de Siderastrea e,
à direita, uma colônia de Mussismilia braziliensis......................................................25
Figura 2. Filogenia da Ordem Scleractinia baseada no marcador molecular COI
retirada de Kitahara et al. (2010)................................................................................26
Capítulo 1
Figure 1. Bayesian phylogenetic inference for ―Siderastrea Complex‖ using the
molecular marker ITS; Posterior probabilities > 0.9 are indicated in black squares.
Morphological identifications are represented by symbols = Siderastrea radians;
= S. stellata.........................................................................................................38
Figure 2. Bayesian phylogenetic inference for ―Siderastrea Complex‖ using the
molecular marker CAG; Posterior probabilities > 0.9 are indicated in black squares.
Morphological identifications are represented by symbols = Siderastrea radians;
= S. stellata........................................................................................................39.
Figure 3. Bayesian phylogenetic inference for ―Siderastrea Complex‖ using the
molecular marker SRP54; Posterior probabilities > 0.9 are indicated in black squares.
Morphological identifications are represented by symbols = Siderastrea radians;
= S. stellata.........................................................................................................40
Figure 4. Multi-locus Time-calibrated Bayesian Inference of ―Siderastrea Complex‖
using a concatenated dataset of the three molecular markers ITS, CAG and SRP54;
The divergence times are shown in the main nodes, with 95% HPD in parentheses.
Posterior probabilities > 0.9 are indicated in black
squares……………………………………………………….................................……..41
Figure 5. Median joining haplotype network for the three molecular markers, ITS,
CAG, SRP54, using samples for the two species Siderastrea radians and S. siderea;
circle sizes represent haplotype frequencies; colors on the haplotype networks
represent genetic groups suggested by BAPS. The Pie Charts represent the
frequency of genetic groups indicated by BAPS using samples for the two species,
within sampling points; the numbers represent the sampling sites and the colors
represent the groups inferred by BAPS for each marker. Colors: (ITS) red = S.
radians, dark blue = S. siderea, beige = cluster in S. siderea (see Figure 1); (CAG)
yellow = cluster I, green = cluster II, blue = cluster III; (SRP54) purple = cluster I,
cyan blue = cluster
II...……………………………………………………………………........……...…………42
Figure 6. Mantel test for Siderastrea radians and S. siderea using the three molecular
markers ITS, CAG and SRP54. The p-value and R² of each analysis are indicated in
the graphs …….....………………………………..………….................................…….47
Figure 7. Mismatch distribution analysis for Siderastrea radians and S. siderea using
the three molecular markers ITS, CAG and SRP5................………………………….47
Figure 8. The demographic analysis Extended Bayesian Skyline Plot for Siderastrea
siderea for all markers together and for each marker separately. Median shown in
black line and the 95% HPD interval shown in gray
line.………………………………………………………………………........…………….48
Figure 9. The demographic analysis Extended Bayesian Skyline Plot for Siderastrea
radians for all markers together and for each marker separately. Median shown in
black line and the 95% HPD interval shown in gray line…....................................….48
Figure 10. Morphological results. (A) Principal Components Analysis performed with
six morphological traits of sampled colonies. Each point in the graph represents a
colony. In (1), the graph is colored by localities, and acronyms represent corallites
illustrated in B; in (2) the graph is colored by ITS groups; in (3) the graph is colored
by CAG clusters of BAPS; in (4) the graph is colored by SRP54 clusters of BAPS. (B)
Photography of corallites from different colonies with different morphology. They are
indicated in A – 1. The acronym indicates the locality and the number of the
individual: cf = Cabo Frio; co = Coruripe; rn = Rio Grande do Norte/P. Búzios; bts =
Bahia de Todos os Santos; ita = Itacimirim; sjm = S.J. Milagres; ps = P.
Seguro………......................................................................………............................50
Capítulo 2
Figure 1. Modeled distributions of Mussismilia braziliensis for present (0k) and LGM
(21k) scenarios. In the left figure (0k), the continental shelf is submerged. In the right
figure (21k), the continental shelf is exposed and represented by a gray band along
the coast. Suitability means how suitable the environment is for the occurrence; the
values are based on an ensemble of the five used algorithms Bioclim, Mahalanobis,
Domain-Gower, SVM and MaxEnt.
…………………………………………………………………………….…..….......…….78
Figure 2. Median joining haplotype network for both markers. Colors represent
sampling localities for ITS and groups inferred by BAPS for MasSC-1. Circle sizes
represent haplotype frequencies ………………………………………..................…..81
Figure 3. Pie chart indicating the diversity distribution along sampling points. (A)
Frequency of haplotypes of ITS (B) Frequency of genetic groups indicated by BAPS
for MaSC-1.……………………………………………………..................……………...81
Figure 4. Mantel test for Mussismilia braziliensis using ITS and MaSC-1. The R² and
p-value of each analysis are indicated on the graph...………..............……………...81
Figure 5. Bayesian phylogenetic inference for ITS and MaSC-1 sequences. The
divergence times of the main nodes are shown, with 95% HPD in parentheses.
Posterior probabilities > 0.9 are indicated in black squares…………….......………..82
Figure 6. The demographic analysis Extended Bayesian Skyline Plot for Mussismilia
braziliensis for ITS and MaSC1, with the median shown in the black line and the 95%
HPD interval shown in the gray
line..……………………………………………………….……………………............…...83
LISTA DE TABELAS
Capítulo 1
Table 1. Localities, number of field sampling number of individuals sampled in field
and database, number of individuals sequenced for each marker (ITS, CAG, SRP54)
and number of individuals used in the morphometric analysis...................................36
Table 2. Diversity indices and neutrality tests for S. siderea and S. radians. N = nº of
individuals; S = nº of polymorphic sites; H = nº of haplotypes; Hd = haplotype
diversity; π = nucleotide diversity; s.d. = standard deviation; r = Harpending‘s
raggedness index; * = statistically significant values (p<0.05).…..............................43
Table 3. Population pairwise ΦST for ITS, CAG and SRP54, respectively. S. siderea
is below the diagonal and S. radians is above the diagonal. * = statistically significant
values (p<0.05).………………………………………….…..........................................45
Table 4. Mean, standard deviation and amplitude of morphometric measures for
localities that we have skeletal samples. Metric values in millimeters.………...........51
Capítulo 2
Table 1. Diversity indices and neutrality tests for Mussismilia braziliensis. N = nº of
individuals; S = nº of polymorphic sites; H = nº of haplotypes; Hd = haplotype
diversity; π = nucleotide diversity; s.d. = standard deviation; * = statistically significant
values (p<0.05)……………………………………………………........................……..80
Table 2. Population pairwise ΦST for Mussismilia braziliensis. ITS is below and
MaSC-1 is above the diagonal.…………………………………………….......………..80
Table 3. Hierarchical analysis of molecular variance (AMOVA) was used to estimate
levels of genetic differentiation among populations (FST), between groups of
populations or regions (FCT) and between populations within regions
(FSC).………………………………………………………………………….........………80
SUMÁRIO
INTRODUÇÃO GERAL ................................................................................... 17
1. Recifes de corais e Biogeografia: distribuição da biodiversidade e regiões
marginais ..................................................................................................... 17
2. Recifes de corais Brasileiros ................................................................. 19
3. Ferramentas para estudar os padrões atuais e os processos históricos de
formação da diversidade da fauna coralínea brasileira ........................... 20
4. O „Complexo Siderastrea do Atlântico‟ e a espécie Mussismilia braziliensis
...................................................................................................................... 22
OBJETIVOS DA TESE .................................................................................... 26
CAPÍTULO I ..................................................................................................... 28
Phylogeography of the genus Siderastrea (Anthozoa, Scleractinia) in
Southwest Atlantic: insights about the historical formation of coral
biodiversity in marginal reefs .................................................................... 28
Abstract ....................................................................................................... 28
Introduction ................................................................................................. 29
Material and Methods ................................................................................. 32
Results ......................................................................................................... 36
Discussion ................................................................................................... 51
References ................................................................................................... 59
CAPÍTULO II .................................................................................................... 69
Paleoclimatic distribution and phylogeography of Mussismilia braziliensis
(Anthozoa; Scleractinia), and endemic coral of Brazilian reefs .............. 69
Abstract ....................................................................................................... 69
Introduction ................................................................................................. 70
Results ......................................................................................................... 77
Discussion ................................................................................................... 83
References ................................................................................................... 88
Supplementary information ....................................................................... 88
DISCUSSÃO GERAL .................................................................................... 101
CONCLUSÕES GERAIS ............................................................................... 104
REFERENCIAS BIBLIOGRÁFICAS .............................................................. 105
ANEXOS............................................................................................................126
17
INTRODUÇÃO GERAL
1. Recifes de corais e Biogeografia: distribuição da biodiversidade e regiões
marginais
Os recifes de corais são ecossistemas marinhos costeiros mantidos pelo
balanço entre processos de bioconstrução, por organismos capazes de depositar
estruturas de carbonato de cálcio (principalmente corais escleractíneos
zooxantelados), e processos de bioerosão, por organismos que escavam, raspam ou
dissolvem estas estruturas (Glynn and Manzello 2015, Schmidt and Richter 2013).
Este balanço confere grande complexidade e heterogeneidade estrutural aos recifes,
o que lhes permite abrigar uma grande diversidade de organismos (Bozec et al.
2015). Embora ocupem uma área de cerca de 0.1 % de toda a área dos oceanos,
possuem cerca de 34.3 % de toda a sua diversidade (Reaka-Kudla 1997), sendo
conhecidos como um dos ecossistemas mais diversos do planeta (Connell et al.
1978).
Os recifes de corais são restritos a ambientes tropicais de águas rasas (Veron
1995) devido a dois motivos principais: a biomineralização da aragonita, principal
tipo de carbonato de cálcio do esqueleto dos organismos bioconstrutores, diminui a
baixas temperaturas (Muller-Parker and D‘Elia 2015, Sheppard et al. 2009); e além
disso, até 90% da nutrição dos corais escleractíneos vem da sua associação com
algas dinoflageladas do gênero Symbiodinium, mais diversas e abundantes em
regiões com alta incidência de luz (Muller-Parker and D‘Elia 2015, Sheppard et al.
2009).
A diversidade desses ecossistemas não é homogeneamente distribuída na
região tropical. O padrão mais evidente é conhecido como ―bullseye‖, no qual a
diversidade é alta em regiões conhecidas como centros de diversidade (e.g.
Arquipélago Indo-Malaio no Oceano Indo-Pacífico e Caribe no Oceano Atlântico) e
diminui em direção as zonas marginais (Veron 1995, Cowman et al. 2017).
Entretanto, ao contrário do que é observado em ambientes terrestres, os centros de
diversidade de recifes de corais não coincidem com seus centros de endemismo
(Hughes et al. 2002). Regiões marginais possuem as maiores proporções de
18
espécies endêmicas ao passo que a maior parte das espécies dos centros de
diversidade são amplamente distribuídas. A detecção deste padrão chamou atenção
para a importância das regiões marginais para a diversidade (Bowen et al. 2013,
2016).
Recifes de corais marginais são aqueles que se estabelecem em condições
ambientais não ideais ou em locais sujeitos a grandes flutuações ambientais
(Kleypas, et al. 1999, Perry and Larcombe 2003). Em geral, ocorrem nas bordas da
distribuição desses ecossistemas possuindo populações e diversidade genética
menor em relação às centrais (Kawecki 2008, Nunes et al. 2011, Noreen et al. 2015,
Grupstra et al. 2017). A condição marginal favorece a ocorrência de variações
fenotípicas e genotípicas devido a seleção natural e deriva genética, gerando
diversidade e processos de especiação (Rocha et al. 2008, Quenouille et al. 2011).
De acordo com alguns autores, outros mecanismos como hibridação e introgressão
também parecem se intensificar nas bordas da distribuição das espécies (Willis et al.
2006, Frade et al. 2010, Richards and Hobbs 2015).
A incorporação de uma perspectiva biogeográfica histórica para explicar a
distribuição da diversidade em ambientes marinhos tropicais indica que muitas
espécies surgiram em regiões marginais (Heck and McCoy 1978, Gaston 2003,
Rocha et al. 2008, Hodge et al. 2013, Rocha et al. 2005); outras se mostraram
amplamente distribuídas no passado e são atualmente restritas a essas regiões
(Bellwood and Meyer 2009), ao passo que muitas colonizaram áreas marginais a
partir de eventos de dispersão (Evans et al. 2016). Entretanto, a magnitude em que
esses eventos ocorrem é desconhecida.
Uma revisão recente discute padrões temporais de origem da diversidade em
ambientes recifais utilizando peixes recifais como organismo modelo, que é um dos
grupos mais estudados. Em seu trabalho, os autores discutem a dificuldade em se
construir estes padrões devido à escassez de dados sobre o assunto, principalmente
em recifes de corais do Oceano Atlântico (Cowman et al. 2017). Ainda, o trabalho
destaca que o investimento nessa área de estudo, o que inclui trabalhos com
fósseis, estudos filogenéticos, tempos de divergência e estudos populacionais são
essenciais para o avanço nessa área de conhecimento.
19
2. Recifes de corais Brasileiros
Os recifes de corais brasileiros se estendem de forma descontinua ao longo
da costa brasileira por aproximadamente 3.000 Km, entre 0º50‘S a 18º00‘S.
Apresentam variadas morfologias, tais como bancos recifais paralelos e adjacentes a
costa, recifes em franja, patch reefs, um atol e uma formação endêmica de
crescimento em forma de cogumelo designada ‗chapeirão‘ (Leão et al. 2003). Eles
são considerados marginais devido à sua distância do centro de diversidade
Caribenho e devido às condições ambientais não ideais em que se desenvolvem
(Leão et al. 2003, Dutra et al. 2006, Suggett et al. 2012). Dentre estas condições,
destacam-se uma plataforma continental predominantemente curta, com pouca área
para o estabelecimento de recifes, e uma alta turbidez da coluna d‘água devido à
grande quantidade de sedimentos oriundos do desague dos rios, além da erosão
costeira e da ressuspensão desses sedimentos por ventos do sul (Leão and
Dominguez 2000, Castro and Pires 2001, Leão et al. 2003, Segal et al. 2008).
Recentemente, entretanto, os recifes brasileiros foram apontados como um centro
de diversidade secundário para peixes no Oceâno Atlântico (Pinheiro et al. 2018).
A fauna coralínea dos recifes brasileiros é conhecida pela baixa diversidade
de corais zooxantelados da ordem Scleractinea e pelo alto endemismo (Laborel
1969). No total, são registrados vinte e uma espécies, sendo que quatorze também
ocorrem no Caribe e sete são endêmicas (Neves et al. 2006). Dentre as endêmicas,
três possuem congêneres no Caribe, Siderastrea stellata, Astrangia braziliensis e
Meandrina braziliensis e quatro, pertencem ao gênero Mussismilia, restrito à costa
do Brasil. Outra característica peculiar dos corais zooxantelados brasileiros é a
predominância do formato maciço hemisférico, característico das espécies de recifes
antigos (Leão 1983, Leão and Kikuchi 2005), ao passo que os recifes atuais no
caribe apresentam predominantemente espécies com formas ramificadas e porosas,
representadas, por exemplo, pelos acroporídeos (Pandolfi and Jackson 2006).
Estudos indicam que a formação atual dos recifes brasileiros é bastante
recente uma vez que provavelmente ocorreu após as últimas glaciações no
Pleistoceno (Ludt and Rocha 2014). Pesquisadores discutem que variações
climáticas neste período causaram regressões e transgressões no nível do mar em
20
todo o mundo, afetando principalmente ecossistemas costeiros como os recifes de
corais (Budd 2000, Pellissier et al. 2014, Ludt e Rocha 2014). Estima-se que no
último máximo glacial, há aproximadamente 21 mil anos, a linha de costa desceu
cerca de 120 metros, deixando exposta a plataforma continental onde recifes
ocorrem hoje, de forma que a colonização atual destes ambientes possivelmente
ocorreu apenas depois deste evento.
No Brasil, estudos que buscam entender se as variações pleistocênicas no
nível do mar podem ter interferido na distribuição atual da diversidade de corais são
poucos. Alguns sugerem colonização recente de outros lugares do Oceano Atlântico,
principalmente do Caribe, devido a semelhança entre suas faunas (Leão et al. 2003).
Outros hipotetizam que a região de montanhas submersas de Vitória – Trindade,
situada próximo ao Banco de Abrolhos de forma perpendicular à costa (Pinheiro et
al. 2014), pode ter se mantido climaticamente estável em relação a outras regiões,
servindo como áreas de refúgio para espécies recifais e permitindo a sua
persistência ao longo do tempo (Leão 1983, Nunes et al. 2008). Estes refúgios
seriam, então, fontes de colonização para os recifes atuais. Estudos moleculares
recentes com peixes e com a espécie de coral Mussismilia hispida mostram
evidências da ocorrência destes refúgios em montanhas submersas afastadas da
costa (Pinheiro et al. 2017, Peluso et al. 2018). Entretanto, a formação da
diversidade de corais na costa brasileira é um assunto que ainda precisa ser melhor
explorado.
3. Ferramentas para estudar os padrões atuais e os processos históricos de
formação da diversidade da fauna coralínea brasileira
Diferentes abordagens metodológicas tem sido utilizadas para estudar
padrões atuais de diversidade e processos históricos responsáveis pela sua
formação. Análises de variação morfológica constituem uma das primeiras e ainda
hoje uma das principais ferramentas de descrição da diversidade tanto intra quanto
interespecífica (Monteiro and Reis 1999, Budd and Stolarski 2011). Ao serem
correlacionadas com variações ambientais ou com variações genéticas ao longo da
sua distribuição, variações morfológicas podem ajudar a construir hipóteses sobre a
formação da biodiversidade, bem como apoiar hipóteses já existentes (Todd 2008).
21
Para corais escleractíneos, a grande quantidade de traços morfológicos quantitativos
tem exigido a utilização de técnicas multivariadas, estando as análises de
componentes principais e as análises discriminantes entre as mais utilizadas para
este grupo (Filatov et al. 2010, Menezes et al. 2013, Paz-García et al. 2015).
Na segunda metade do século XX, o avanço nos métodos de obtenção e
análise de dados moleculares permitiu estudos cada vez mais aprofundados sobre a
formação da diversidade. A Filogeografia surge neste contexto, na década de 80,
como uma área da ciência que utiliza conceitos de Genética de Populações,
Sistemática e Biogeografia para estudar os princípios e processos que determinam a
distribuição geográfica de linhagens genealógicas (Avise et al. 1987). Os primeiros
trabalhos filogeográficos foram baseados em dados de DNA mitocondrial e
consistiam basicamente em sobrepor genealogias à distribuição das amostras
avaliadas a fim de encontrar concordância entre as linhagens e sua localização no
espaço (Martins and Domingues 2011). Nos últimos anos, a incorporação dos
métodos de coalescência nas análises filogeográficas tem permitido inferir
complexos cenários demográficos do passado a partir de informações genéticas
atuais (Avise 2009). Um passo importante dessa área da ciência foi o fato de poder
ser aplicado tanto a estudos macro quanto micro evolutivos, possibilitando avaliar
processos evolutivos e biogeográficos em diferentes escalas (Avise 2009).
As metodologias da filogeografia tem sido amplamente aplicadas para testar
hipóteses sobre a influência de eventos como variações no nível do mar, deriva dos
continentes, correntes e outras barreiras semipermeáveis na história evolutiva dos
organismos marinhos (Mirams et al. 2011, Baums et al. 2014, Ludt and Rocha 2014,
Dohna et al. 2015). No Brasil, existe um grande esforço em ampliar os estudos
filogeográficos com organismos marinhos, de forma que eles tem sido realizados
com diversos organismos como peixes, esponjas, poliquetas, moluscos, crustáceos
e cnidários (Rocha et al. 2008, Lazoski et al. 2011, Rua et al. 2011, Stampar et al.
2012, da Silva et al. 2016, Neves et al. 2016, Souza et al. 2016, Nunes et al. 2016,
Pinheiro et al. 2017), entretanto, poucos foram realizados até o momento com corais
escleractíneos (Neves et al. 2008, Nunes et al. 2011, Peluso et al. 2018).
22
Recentemente, modelagens de distribuição também tem sido utilizadas para
entender a história biogeográfica da diversidade. Esta técnica identifica os fatores
ambientais determinantes da distribuição espacial atual das espécies e projeta a sua
possível distribuição no espaço e tempo, podendo inferir mudanças na distribuição
de espécies e populações (Peterson et al. 2001). Em ambientes terrestres, essa
metodologia foi utilizada para localizar áreas climaticamente estáveis no tempo
geológico, que poderiam ser locais de refúgios em casos de flutuações climáticas
(Carnaval et al. 2009, Peres et al. 2015); também foi utilizada para inferir eventos de
expansão e retração de biomas e antigas conexões entre florestas tropicais
(Carnaval and Moritz 2008, Leite et al. 2015, Sobral-Souza et al. 2015, Bartoleti et al.
2017). Em ambientes marinhos, modelagens de distribuição tem sido empregadas
principalmente para prever a distribuição potencial atual ou futura das espécies
(Tittensor et al. 2009, (Saupe et al. 2014); porém, poucos estudos tem realizado
modelagens para o passado (Assis et al. 2014, Pellissier et al. 2014).
Dada a dificuldade e as incertezas associadas a estudos que tentam entender
processos históricos de formação da diversidade, a utilização conjunta de diferentes
metodologias tem sido recomendada por diversos autores (Knowles et al. 2007,
Carnaval and Moritz 2008, Collevatti et al. 2015). De acordo com Gavin et al. (2014),
que faz uma revisão sobre abordagens para estudar refúgios climáticos, a
porcentagem de trabalhos que associam múltiplas linhas de evidência para inferir
esses eventos passou de 17% entre 1999 e 2003 para 44% em 2013, tratando-se de
uma tendência que vem crescendo com o passar dos anos. De acordo o autor, a
combinação de diferentes técnicas pode auxiliar a inferir histórias evolutivas
complexas, difíceis de serem analisadas apenas por uma perspectiva.
4. O „Complexo Siderastrea do Atlântico‟ e a espécie Mussismilia braziliensis
Pertencentes a Ordem Scleractinia, o gênero Siderastrea e a espécie
Mussismilia braziliensis são importantes componentes das comunidades coralíneas
da costa do Brasil e possuem um papel considerável na construção da estrutura
carbonática de alguns recifes. Siderastrea é o coral dominante na base dos recifes
do Atol das Rocas, ao passo que Mussismilia brasiliensis é a principal construtora
dos chapeirões dos bancos de Abrolhos (Leão et al. 2003). Ambos são corais
23
coloniais, maciços e de crescimento hemisférico ou incrustante, típico dos corais
brasileiros.
O gênero Siderastrea de Blainville, 1830, compõe a Família Siderastreidae e
se diferencia dos outros gêneros principalmente por seus septos seguirem um plano
hexameral (Neves 2004) (Figura 2). Possui uma distribuição cosmopolita e é
representado por quatro espécies: S. savigniana, que ocorre no Indo – Pacífico; S.
siderea e S. radians que ocorrem em todo o Atlântico; e S. stellata que era
considerada endêmica no Brasil, mas que foi registrada em 2017 no Golfo do México
(Neves 2004, García et al. 2017). De ocorrência restrita a costa oeste do Panamá, S.
glynni, era tida como uma quinta espécie, porém, foi recentemente sinonimizada a S.
siderea (Glynn et al. 2016).
O grupo possui uma alta resistência a variações de temperatura, salinidade e
sedimentação, além de ser encontrado em uma grande amplitude de profundidade
(0 a 60 m) (Leão et al. 2003, Cordeiro et al. 2015). Informações sobre sua
reprodução indicam que S. siderea é desovadora com fecundação externa enquanto
as outras duas são incubadoras com fecundação interna (Neves and Da Silveira
2003). Estudos sobre variação e estruturação genética do gênero na costa do Brasil,
realizados com marcadores moleculares, particularmente com isoenzimas e
marcadores nucleares, apontam para uma capacidade de dispersão moderada para
S. radians e S. stellata (Neves et al. 2008, Nunes et al. 2011).
A morfologia altamente variável dessas espécies tem causado grande
dificuldade na sua taxonomia, motivo pelo qual são frequentemente denominados
―Complexo Siderastrea do Atlântico‖ (Neves 2004, Menezes et al. 2013). Entretanto,
estudos recentes tem indicado diferenças diagnósticas entre elas: S. siderea
apresenta traços morfológicos com valores maiores e ciclos septais sempre
completos, S. radians apresenta traços morfológicos menores e ciclos septais nunca
completos ao passo que S. stellata apresenta morfologia intermediária, podendo ou
não ter ciclos septais completos (Neves et al. 2010).
Dados moleculares, entretanto, apontam para informações contraditórias.
Enquanto um estudo realizado com isoenzimas sugere que os grupos genéticos
24
encontrados no Brasil são as espécies S. radians e S. stellata (Neves et al. 2008),
outro, com marcadores nucleares sugere que os grupos genéticos encontrados são
as espécies S. radians e S. siderea (Nunes et al. 2011). Forsman et al. (2005), ao
realizarem trabalhos filogenéticos com o gênero, aponta grande similaridade entre S.
radians e S. stellata. Entretanto, no período do estudo, os autores não dispunham da
informação da existência de pelo menos duas espécies de Siderastrea na costa do
Brasil, de forma que o trabalho pode ter apresentado algum viés amostral e
taxonômico. Apesar dos avanços, ainda é um grupo de taxonomia controversa, de
forma que a realização de estudos sobre como processos históricos podem ter
influenciado na sua diversidade atual pode auxiliar nas incongruências taxonômicas
e melhorar o entendimento sobre o grupo.
A espécie Mussismilia braziliensis compõe o gênero Mussismilia Ortmann,
1890, que é endêmico da costa do Brasil (Figura 1 e 2). Dentre as quatro espécies
do gênero, é a que possui a menor distribuição, ocorrendo entre o norte da Bahia e o
norte do Espírito Santo, em aproximadamente 800 Km de costa. As outras espécies
possuem ocorrência mais ampla: Mussismilia hispida é registrada do Maranhão a
Santa Catarina; Mussismilia harttii ocorre do Rio Grande do Norte ao Espírito Santo;
Mussismilia leptophylla é registrada no Maranhão e na costa da Bahia (Castro and
Pires 2001, Leão et al. 2003, Amaral et al. 2007, Budd et al. 2012). Apesar de ser
espacialmente restrita, M. braziliensis é uma das espécies mais abundantes em
regiões como o Arquipélago de Abrolhos, sendo menos abundante em recifes ao
norte da Bahia (Leão et al. 2003).
Estudos sobre a história de vida de M. braziliensis mostram que é uma
espécie de reprodução anual que realiza fecundação externa – os gametas são
liberados na água e a larva passa mais tempo sujeita a ação da movimentação da
água (Pires et al. 1999). Devido a estas características reprodutivas, é esperado que
possua uma ampla capacidade de dispersão, entretanto, trabalhos empíricos sobre
o assunto não existem. Resultados de experimentos in vitro e o fato de possuírem
pólipos relativamente grandes (~8mm) indicam que M. braziliensis pode resistir às
condições de alta sedimentação característica da costa do Brasil (Loiola et al. 2013,
Tenório 2016). Porém, devido a distribuição restrita, é considerada uma espécie
vulnerável a impactos antrópicos e mudanças climáticas (Francini-Filho et al. 2008,
25
Garcia et al. 2013, Leão et al. 2016, Mazzei et al. 2016). O entendimento sobre a
diversidade atual desta espécie e sobre como pode ter sido influenciada por
processos históricos é de grande importancia para compreender o seu
comportamento diante das atuais ameaças ambientais.
Figura 1. Imagens dos corais estudados. À esquerda, uma colônia de Siderastrea e,
à direita, uma colônia de Mussismilia braziliensis. Fotos: Naália Menezes
10 cm
6,5 cm 10 cm
26
Figura 2. Filogenia da Ordem Scleractinia baseada no marcador molecular COI
retirada de Kitahara et al. (2010).
27
OBJETIVOS DA TESE
O objetivo geral deste trabalho foi estudar os processos históricos
responsáveis pela diversidade de corais escleractíneos da costa do Brasil. Para isso,
utilizamos os grupos ―Complexo Siderastrea‖ e a espécie endêmica Mussismilia
braziliensis.
Os objetivos específicos da tese foram:
Avaliar a variabilidade e estrutura genética do ‗Complexo Siderastrea‘ e da
espécie Mussislimia braziliensis na costa do Brasil
Estimar relações filogenéticas e tempos de divergência entre os indivíduos
dentro do ‗Complexo Siderastrea‘ e da espécie Mussislimia braziliensis na
costa do Brasil
Inferir eventos demográficos para os grupos dentro do ‗Complexo
Siderastrea‘ e da espécie Mussislimia braziliensis na costa do Brasil
Relacionar os resultados das análises baseadas em dados moleculares à
resultados de análises morfológicas e de modelagem de nicho para os
grupos de corais estudados
28
CAPÍTULO I
Phylogeography of the genus Siderastrea (Anthozoa, Scleractinia) in Southwest Atlantic: insights about the historical formation of coral biodiversity in marginal reefs
Abstract
Throughout the Atlantic Ocean, Brazilian coral reefs have a marginal and
young formation that probably started to develop after the last sea level variations of
the Pleistocene. Here we used a phylogeographic approach and morphological
information to evaluate hypotheses about the influence of past events on the current
distribution of scleractinian biodiversity in Brazilian reefs using the genus Siderastrea,
a widely distributed group throughout the Atlantic Ocean. The phylogenetic results
indicated that the two species found on the Brazilian coast are very similar to the
Caribbean congeners S. radians and S. siderea, suggesting the need of broad
taxonomical revision of the group. Genetic diversity, structure and demography in
both species did not show evidence of recent colonization from the Caribbean or from
possible Pleistocene refugia in submerged seamounts near Abrolhos bank, which
indicated that the species of Siderastrea may have maintained their current latitudinal
amplitude of occurrence since the Pleistocene period. Our data also corroborate
hypothesis about the presence of phylogeographic barriers along the Brazilian coast.
This study is important for understanding the historical biogeographic process
responsible for assembling the current marginal scleractinian biodiversity of Brazilian
reefs.
29
Introduction
Corals of the Order Scleractinia are keystone groups of coral reefs due to their
role in building one of the most diverse and productive ocean ecosystems (Moberg
and Folke 1999, Knowlton 2001, McClanahan 2003). Centers of scleractinian
diversity, such as the Coral Triangle in the Indo-Pacific Ocean and Caribbean reefs in
the Atlantic Ocean, have a well-known ecological relevance for marine biodiversity,
acting as sources for colonization of other regions and improving their resilience
capacity (Myers et al. 2000, Hughes et al. 2002, Roberts et al. 2002, Selig et al.
2014). The marginal areas of these corals‘ distribution range, however, have their
importance for biodiversity that has only recently been evidenced. Several works
indicate that marginal regions such as the Hawaiian Archipelago (Waldrop et al.
2016) and the Eastern Tropical Pacific (Hellberg et al. 2016), known for relative low
diversity and high endemism, can act as biodiversity sources, exporting genetic
diversity and morphological innovations (Budd and Pandolfi 2010, Hodge et al. 2011,
Bowen et al. 2013, 2016). However, most studies with corals are still focused on
Indo-Pacific Ocean areas, while marginal reefs in the Atlantic Ocean are still less
studied (Rocha et al. 2008, Nunes et al. 2011, Pinheiro et al. 2018).
Marginal coral reefs are known for their sub-optimal ecological conditions for
most organisms and high environmental fluctuations (Kleypas, et al. 1999). They
generally occur at the edges of these ecosystems‘ distribution, with populations and
genetic diversity lower than the central ones (Kawecki 2008) Nunes et al., 2011,
Noreen et al. 2015, Grupstra et al. 2017). The marginal conditions favor genetic and
phenotypic variations due to natural selection and genetic drift, which may lead to
diversification processes (Kawecki 2008, Nunes et al. 2011, Noreen et al. 2015,
Grupstra et al. 2017). Other important mechanisms, such as hybridization and/or
introgression, are also common at the edges of species ranges (Willis et al. 2006,
Frade et al. 2010, Richards and Hobbs 2015).
In the Atlantic Ocean, Brazilian coral reefs are considered marginal due to
their distance from the Caribbean center of diversity and their turbid waters,
unsuitable for coral growth (Leão et al. 2003, Suggett et al. 2012). They are
discontinuously distributed along ~3000 km of the coast and are subject to different
levels of sediment discharge from rivers/coastal erosion and re-suspension from
30
prevailing southerly winds (Leão and Dominguez 2000, Castro and Pires 2001, Leão
et al. 2003, Segal et al. 2008).
Studies indicate that the formation of the current reefs‘ structures is very
recent, since the sea level dropped about 120 m during the Last Glacial Maximum
(~21 Ka), when the present-day continental shelf was exposed (Ludt and Rocha
2015). The origin of their diversity, however, is little known. Some studies suggest
colonization from other regions of the Atlantic Ocean, mainly from the Caribbean,
because of the similarity between their fauna (Leão et al. 2003). Other authors
hypothesize that the region of submerged mountain Vitória - Trindade, located
perpendicular to the coast and near to the Abrolhos Bank (Pinheiro et al. 2014), may
have remained climatically stable, serving as a refugium for reef species and allowing
their persistence over time (Leão 1983, Pinheiro et al. 2017); thus, these refugia
would be sources of colonization for the present reefs. Recently, evidence supporting
both hypotheses was observed for the coral Mussimilia hispida (Peluso et al. 2018).
However, this topic is still rarely explored for Brazilian scleractinian corals, if we
consider the complexity of evolutionary studies and that species could respond in
different ways to environmental events over time.
Siderastrea is an important genus of reef-building coral on the Brazilian coast,
occupying different environments and extreme conditions of temperature,
sedimentation and ocean acidification (Laborel 1969, Lirman et al. 2002, Castillo et
al. 2014, Horvath et al. 2016). The genus exhibits fossil records dating from the
Cretaceous (~130 Ma) in places such as the Czech Republic (Eliásová 1997),
Germany (Löser 1998), Jamaica (Mitchell 2002), Mexico (Baron-Szabo et al. 2006),
Oman (Metwally 1996), Slovenia (Turnsek 1997), Texas, USA (Wells 1933) and
Sergipe, Brazil (Mascarenhas 2004). However, it is composed of few living species.
Siderastrea savignyana occurs throughout the Indo – Pacific; Siderastrea siderea
occurs in the eastern Pacific and the whole Atlantic Ocean (Glynn et al. 2016),
Siderastrea radians has an Amphi-Atlantic distribution (Neves et al. 2008) and
Siderastrea stellata, usually considered endemic to South Atlantic, was recently
reported in the Gulf of Mexico (Neves et al. 2010, García et al. 2017).
The Atlantic siderastreids have a long history of taxonomical controversies due
to the uncertain boundaries among species and their phylogenetic proximity, and
31
they are commonly referred to as the ‗Atlantic Siderastrea Complex‘ (Werner 1996,
Neves 2004). Although several studies have ratified their specific status (Neves and
Da Silveira 2003, Neves et al. 2008, 2010), some issues are still unclear. While an
extensive isoenzymatic study along the coast shows that the two genetic groups
found in Brazil are morphologically characterized as S. stellata and S. radians (Neves
et al. 2008), a comparative analysis using intronic regions shows that Brazilian
siderastreids are very similar to S. radians and S. siderea (Nunes et al. 2011). Thus,
questions as whether Brazilian siderastreids are composed of multiple ecomorphs of
two phenotypically plastic species (S. radians and S. siderea) found in the Caribbean,
or if S. stellata is a third species, remain uncertain. The absence of studies about the
historical diversification of Siderastrea lineages in a marginal region such as the
Brazilian coast could be an aggravating factor for these controversies.
In this work, we investigated historical biogeographic processes that could
have influenced the diversification and current diversity distribution of the ‗Atlantic
Siderastrea complex‘ in the marginal Brazilian coral reefs through a phylogeographic
approach. Our specific objectives were (1) to identify the siderastreid species
occurring on the Brazilian coast and (2) to test a biogeographic hypothesis that could
explain the genetic diversity observed in Brazilian siderastreids. We tested the
following hypotheses: (i) recent colonization from the Caribbean; (ii) recent
colonization from Pleistocene refugia in the submarine mountain chain near Abrolhos
Bank; (iii) colonization from both cited regions; (iv) absence of change in the
latitudinal amplitude of occurrence over time. If (i) is true, we expect to observe
ancient lineages and higher genetic diversity in populations closer to the Caribbean;
if (ii) is true, we would also detect ancient lineages, but higher genetic diversity in
populations near the Abrolhos region; if (iii) is true, we expect to find two centers of
diversity; and if (iv) is true, we would detect absence of genetic structure.
Additionally, we expect to find evidence of recent demographic expansion if (i), (ii)
and (iii) are true and no signs of recent demographic fluctuations if (iv) is the correct
hypothesis.
To address these objectives, we sequenced three nuclear DNA regions of
Siderastrea samples, inferred their phylogenetic relationships and lineage divergence
times, and estimated the populations‘ genetic diversity, structure and demographic
patterns. We compared these genetic data to morphological information and, based
32
on our results, we discussed the possible biogeographic events that influenced the
diversification and structure of the ‗Atlantic Siderastrea Complex‘ in the Southwest
Atlantic.
Material and Methods
Study sites, sample collection and identification
We sampled fragments of Siderastrea (~5 cm) from 16 sites along the
Brazilian coast (Table 1). We chose colonies that were at least 2 m apart and we
used a hammer and chisel to remove them, taking care to minimize the damage to
the whole colony. We scraped the fresh tissue off the living surface, put it in vials of
1.5 ml containing anhydrous alcohol or guanidine thiocyanate solution (4 M guanidine
thiocyanate, 0.1% N-lauroyl sarcosin sodium, 10 mM Tris pH8, 0.1 M 2-
mercaptoethanol), and stored it at freezing temperature until extraction. The
skeletons were labeled and bleached overnight in a solution of 2% sodium
hypochlorite, rinsed and air-dried for morphotype assignment, since field identification
was infeasible (Neves et al. 2010). Skeleton fragments of Abrolhos Region, Tinharé –
Boipeba Archipelago and Atol das Rocas were not collected because of logistical
issues.
The taxonomic identification was primarily based on morphological diagnosis
(Neves 2004, 2010); however, since we did not have the skeletons of all individuals,
we also used an ITS marker as a species ‗barcode‘ region to identify them (Forsman
et al. 2005, Fukami et al. 2004). Although some authors question the power of this
marker to infer relationships at species and lower levels in scleractinian studies
(Vollmer and Palumbi 2004), Forsman et al. (2005) showed that it has appropriate
resolution and phylogenetic signal for Siderastrea and Porites. All individuals were
sampled under permits granted by the Instituto Chico Mendes de Conservação da
Biodiversidade (ICMBio, permit nos. 39090, 50521, 51433). The specimens were
labeled and deposited in the Cnidaria Collection at the ‗Museu de Zoologia da
Universidade Federal da Bahia‘ (UFBA) as follows: Titanzinho/CE – UFBA1163; P.
Búzios/RN – UFBA1167; S.J. Milagres/AL – UFBA1768; Coruripe/AL – UFBA1160;
Itacimirim/BA – UFBA1164; B. T. Santos/BA UFBA1165, 1166; Caramuanas/BA –
UFBA1159, 1169; P. Seguro/BA – UFBA1161; Cabo Frio/RJ – UFBA1162.
33
DNA extraction, amplification and sequencing
The genomic DNA was extracted using a phenol protocol described by Nunes
et al. (2009). Three nuclear markers were used: the Internal Transcribed Subunit
region (ITS), the carbonic anhydrase region (CAG) and the Signal Recognition
Particle 54-kDa region (SRP54). ITS was amplified using primers ITS-1 and ITS-4
(White et al. 1990), and thermal profile had initial denaturation step at 96°C for 2 min;
35 cycles at 95°C for 10 s, 52°C for 30 s and 70°C for 4 min; and extension at 70°C
for 2 min. CAG was amplified using primers 3-550 F and 3-550 R (Macdonald et al.
2011), and thermal profile had initial denaturation step at 95°C for 4 min; 35 cycles at
95°C for 45 s, 62°C for 45 s and 72°C for 2 min; and extension at 72°C for 10 min.
SRP54 was amplified with primers SRP54Madfor and SRP54Madrev2 (Frade et al.
2010), and thermal profile had initial denaturation step at 94°C for 2 min; 35 cycles at
94°C 2min, 52°C for 30 s and 72°C for 1 min; and extension at 72°C for 2 min. All
PCR reactions were carried out with a total volume of 25µl with 10 ng of genomic
DNA, 3.0 mM MgCl2, 1X of taq buffer, 0.4 mM of dNTP, 0.16 µM of each primer, 1U
of Taq DNA polymerase and milli-q water.
The amplicons were analyzed in a Perkin-Elmer Prism 377 capillary
sequencer. Sequences were aligned using the MAFFT algorithm under the default
strategy (Katoh and Standley 2013), which has been shown to outperform when
indels are plentiful, and manually inspected and edited in MEGA 6.0 (Tamura et al.
2013). Heterozygous sites were first coded according to IUPAC ambiguity codes, and
the phased haplotypes were estimated using a Bayesian method employed in
PHASE (Stephens and Donnelly 2003) based on the input files prepared with Dnasp
v. 5.0 (Librado and Rozas 2006). The gametic phases were inferred with a minimum
posterior probability of 0.9, usually recommended to reduce the number of unsolved
haplotypes with false positives (Garrick et al. 2010).
Phylogenetic inference and divergence times
We constructed independent Bayesian gene trees using BEAST v.1.7.4.
(Drummond et al. 2012b). The best fit nucleotide substitution models previously
selected by AIC criterion in MEGA 6.0 (Tamura et al. 2013) were JC for ITS and
TN93 and CAG for SRP54. Sequences other genera available on GenBank
34
(https://www.ncbi.nlm.nih.gov/genbank/) were used as outgroups. The outgroups
were chosed based on availability in the data bases and phylogenetic proximity with
Siderastrea (Figure x). Coscinaraea columna (AB441406.1) and Psammocora
contigua (AY722784.1) were used to root the ITS tree; Acropora austera
(HQ441841.1), A. millepora (KC493137.1) and Styllopora pistilata (HM748807.1)
were used to root the CAG tree; and Madracis decactis (HQ379122.1), M. formosa
(HQ379131.1) and Pocillopora sp. (EU006863.1) were used to root the SRP54 tree.
We inferred parameters from a run of 200 million steps, with trees sampled every
10,000 steps. After checking the highly effective sample sizes (ESS>200) in Tracer
1.5 (Rambaut and Drummond 2009), the first 20% of trees were discarded as burn-in
in TreeAnnotator. The resulting maximum clade credibility (MCC) trees were drawn in
Figtree 1.4.2 (Rambaut 2009).
We also inferred a concatenate time-calibrated phylogenetic hypothesis in
BEAST v.1.7.4 using fossil record information on S. siderea and S. radians, which
first appeared in the Dominican Republic around 15.7 Ma bp and 7.7 Ma bp,
respectively (Johnson et al. 2008). We used an initial mean mutation rate of 0.004
substitutions/Mya, previously provided by Savard et al. (1993) for ITS, considering a
lognormal relaxed clock and using only the individuals with the three nuclear regions
sequenced. We specified unlinked substitution models, unlinked clock models and
linked tree for the three markers. The analysis was run for 300 million generations,
with a tree-sampling frequency of 10,000. We checked the convergence and effective
sample sizes (ESS>200) in Tracer (Rambaut et al. 2009) and discarded the first 20%
trees. We used Figtree 1.4.2 to draw the resulting MCC tree.
Haplotype networks, genetic diversity and population structure
We constructed haplotype networks in PopART v.1.7 (Leigh & Bryant, 2015),
using the Median-joining algorithm (Bandelt et al. 1999). Because of the presence of
indels, we previously edited the matrices performing a simple coding method
(Simmons and Ochoterena 2000), which counts contiguous gaps as a fifth base
change, implemented in SeqState 1.4.1 (Müller 2006). Molecular diversity indices,
haplotype frequencies and pairwise differentiations among sample sites (ΦST) were
calculated using Arlequin v. 3.5 (Excoffier & Lischer, 2010). Bayesian Analyses of
Population Structure were also conducted for all datasets using BAPS v. 6.0
35
(Corander et al. 2008). We performed ten runs to estimate the most probable number
of genetic groups in our data (k) in a range between 1 and 20.
Demographic analysis
We checked for neutrality and inferred historical demographic processes using
Tajima‘s D (Tajima 1989), Fu‘s Fs (Fu 1997) tests and mismatch distribution
analyses (Harpeding 1994) for each population and each species in Arlequin v. 3.5.
To estimate possible changes in the population size (Ne) through time, we applied
Extended Bayesian Skyline Plot (EBSP) analyses with all markers together and each
locus separately using Beast v. 1.7.4 (Drummond and Rambaut 2007). We unlinked
substitution rates, clock and tree models and specified a linear model of population
size. Runs of 300 million interactions were conducted, with samples taken every
10000 generations. The first 20% samples were discarded as burn-in. Tracer v1.5
was used to check the quality of the parameters.
Morphometric analysis
After identification, we applied an exploratory analysis for morphological
variation. We used a stereomicroscope supplied with a calibrated eyepiece to
measure six characters involved in the description of Siderastrea (Laborel 1969,
Budd 1990, Neves 2004): corallite diameter (corD), columellar diameter (colD), septal
number (sepN), thecal thickness (tecThick), columellar depth (depth), and the
average distance between adjacent sampled calices (corDist) (Neves 2004, Menezes
et al. 2013). Only mature corallites (‗old polyps‘ sensu Soong and Lang 1992) with at
least the third cycle of the septa fully formed were examined. For each fragment,
three corallites were selected for measurements and statistical analyses were based
on the average of the three corallites. We performed a Principal Component Analysis
(PCA). Data were standardized to log (2) to fulfill PCA assumptions. The
Kolmogorov-Smirnov test showed normal distribution for data. Descriptive analyses
were also carried out with mean, standard deviation and amplitude of measures from
corallites used (See Results). We used the vegan (Oksanen et al. 2012) and ggplot2
(Wickham 2009) packages in R environment and Excel 2010 (Microsoft©) for the
analyses. We used samples only from places that we could keep the skeletons:
Fortaleza (n=6), P. Búzios (n=5), S. J. Milagres (n=6), Coruripe (n=5), Itacimirim
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(n=8), BTS (n=8), Caramuanas (n=8), P. Seguro (n=8), Cabo Frio (n=8). We also
included information on S. siderea from other studies to compare with our results
(Neves 2004). Only samples from Fortaleza, P. Búzios, S.J.Milagres, Coruripe and
Cabo Frio had correspondence with genetic data. For other places, we haphazardly
chose the colonies for analysis.
Table 1. Localities, latitude and longitud, number of field sampling number of individuals sampled in field and database, number of individuals sequenced for each marker (ITS, CAG, SRP54) and number of individuals used in the morphometric analysis.
Localities Latitude Longitude Nº field samples
Nº ind. ITS
Nº ind.
CAG
Nº ind. SRP54
Nº ind. Morfometry
1-Panamá 21 21 - - 1 (Neves 2004)
2-Titanzinho, CE -3,707671 -38,46795 10 6 2 - 6 3-A. Rocas -3,866349 -33,817222 30 8 4 10 - 4-P. Búzios, RN -6,008056 -35,10583333 10 5 5 5 5 5-Pernambuco -8,445833 -34,904166 3 3 - - - 6-S.J. Milagres, AL -9,274489 -35,366172 10 2 4 5 6 7-Coruripe, AL -10,16036 -36,134274 10 5 - 4 5 8-Itacimirim, BA -12,60947 -38,021794 30 8 5 8 8 9-B.T.Santos, BA -12,79761 -38,57143263 30 5 - 8 8 10-Caramuanas, BA
-13,13309 -38,736693 30 7 5 8 8
11-T. Boipeba, BA -13,48917 -38,90361111 40 9 5 5 - 12-P. Seguro, BA -13,67 -38,89416667 30 7 4 8 8 13-P. Leste, BA -16,3329 -39,006936 30 5 4 7 - 14-P. Lixa, BA -16,64876 -39,093364 30 5 5 5 - 15-P. Sul, BA -17,68398 -38,96529374 30 4 - 5 - 16-P. Abrolhos, BA -17,77615 -39,05079753 30 6 5 7 - 17-C. Frio, RJ -17,96361 -38,70777778 10 8 5 7 8 Total 384 114 54 92 66
Results
Genetic diversity and sequence features
The ITS, CAG and SRP54 sequences obtained measured 573, 227 and
233 bp, respectively. ITS and SRP54 datasets exhibited high haplotype and
nucleotide diversities, with several gaps and 79 and 43 polymorphic sites,
respectively; CAG was much less variable, with 12 polymorphic sites and no gaps
(Table 2). The three markers showed ambiguous peaks and, after the haplotype
reconstruction in PHASE and the removal of sequences with posterior probability
37
lower than 0.9, we obtained 114, 92 and 53 solved sequences for ITS, SRP54 and
CAG respectively.
Phylogenetic inferences and divergence times
Bayesian phylogenetic inferences presented different results for the three
markers (Figure 1, 2 and 3). The ITS tree showed two well-marked groups, which
were highly similar to the species identified as S. siderea and S. radians by previous
studies (Forsman et al. 2005). Thus, we adopted this species‘ nomenclature to refer
to these two groups throughout the paper. These lineages‘ divergence presents
some correspondence with the clusters indicated by BAPS (see next section),
represented by different colors in Figure 1: while the red cluster is monophyletic, blue
and beige clusters exhibit paraphyly. The CAG tree did not present groups with
strong support, and the SRP54 tree showed two deeply divergent groups. When we
compared the three gene trees, we observed no concordant monophyly among the
groups, although some resemblance in topology should be observed between ITS
and CAG trees (Figure 1 and 2).
The time-calibrated tree using all markers showed that Siderastrea diverged
from the outgroup at ~127.6 Ma [95% highest posterior density (HPD) = 27.1-311.8
Ma]; and the divergence between S. radians and S. siderea occurred at ~29.02 Ma
(95% HPD = 15.6-59.8 Ma). More recent diversifications were also observed, but
were not considered because of the low posterior probability (Figure 4).
Haplotype networks and population structure
Each haplotype network was constructed using samples from all Siderastrea
samples (Figure 5). The ITS network indicated high diversity and two well-marked
groups separated by at least 17 mutational steps for ITS, which correspond to S.
radians and S. siderea; SRP54 network presented two groups separated by 16
mutational steps that have no correspondence with the groups observed for ITS; the
CAG network presented fewer haplotypes and no evident structure (Figure 5). The
ITS and SRP54 networks recover the BAPS groups, but blue and beige ITS groups
did not present marked differences (Figure 5).
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Figure 1. Bayesian phylogenetic inference for ―Siderastrea Complex‖ using
the molecular marker ITS; Posterior probabilities > 0.9 are indicated in black
squares. Morphological identifications are represented by symbols =
Siderastrea radians; = S. stellata.
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39
Figure 2. Bayesian phylogenetic inference for ―Siderastrea Complex‖ using
the molecular marker CAG; Posterior probabilities > 0.9 are indicated in black
squares. Morphological identifications are represented by symbols =
Siderastrea radians; = S. stellata.
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40
Figure 3. Bayesian phylogenetic inference for ―Siderastrea Complex‖ using
the molecular marker SRP54; Posterior probabilities > 0.9 are indicated in
black squares. Morphological identifications are represented by symbols
= Siderastrea radians; = S. stellata.
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Figure 4. Multi-locus Time-calibrated Bayesian Inference of ―Siderastrea Complex‖ using a concatenated dataset of the three molecular markers ITS, CAG and SRP54; The divergence times are shown in the main nodes, with 95% HPD in parentheses. Posterior probabilities > 0.9 are indicated in black squares.
Some geographical differentiation was observed among groups on the
Brazilian coast (Figure 5). Although S. radians and S. siderea occur sympatrically (as
detected in ITS analyses), the former is more frequent in the north, while the latter
occurs mostly in the south (Figure 5). Curiously, the S. siderea beige group identified
by BAPS occurs only in B. T. Santos and Panamá. The CAG groups also present this
north-south disjunction and occurred sympatrically in some areas. SRP54 groups,
however, have no clear geographical structure and both occur in most of the
locations (Figure 5).
Pairwise ΦST values obtained for ITS, CAG and SRP54 sequences showed
some differentiation among localities for S. siderea and S. radians (Table 3).
However, no evidence of isolation by distance was detected (Figure 6).
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Figure 5. Median joining haplotype network for the three molecular markers, ITS, CAG, SRP54, using samples for the two species Siderastrea radians and S. siderea; circle sizes represent haplotype frequencies; colors on the haplotype networks represent genetic groups suggested by BAPS. The Pie Charts represent the frequency of genetic groups indicated by BAPS using samples for the two species, within sampling points; the numbers represent the sampling sites and the colors represent the groups inferred by BAPS for each marker. Colors: (ITS) red = S. radians, dark blue = S. siderea, beige = cluster in S. siderea (see Figure 1); (CAG) yellow = cluster I, green = cluster II, blue = cluster III; (SRP54) purple = cluster I, cyan blue = cluster II.
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Table 2. Diversity indices and neutrality tests for S. siderea and S. radians. N = nº of individuals; S = nº of polymorphic sites; H = nº of haplotypes; Hd = haplotype diversity; π = nucleotide diversity; s.d. = standard deviation; r = Harpending‘s raggedness index; * = statistically significant values (p<0.05).
Localities N S H Hd(s.d.) π (s.d.) D FS R N S H Hd(s.d.) π (s.d.) D FS r
ITS – 573 bp S. siderea S. radians Panamá 15 27 8 0.82(0.05) 0.011(0.006) 0.12 3.3 - 6 2 3 0.55(0.14) 0.001(0.001) -0.19 -0.3 - Titanzinho, CE - - - - - - - - 6 1 2 0.3(0.145) 0.005(0.001) -0.19 0.3 - A. Rocas 2 0 1 0 0 0 0 - 6 8 8 0.94(0.05) 0.005(0.003) 0.12 -2.7* - P.Búzios, RN - - - - - - - - 5 8 8 0.96(0.06) 0.005(0.003) 0.12 -3.6* - Pernambuco - - - - - - - - 3 2 3 0.8(0.12) 0.002(0.002) 0.85 -0.08 - S.J. Milagres, AL - - - - - - - - 2 4 3 0.83(0.22) 0.005(0.003) 1.4 0.46 - Coruripe, AL 1 0 1 0 0 0 0 - 4 3 4 0.75(0.14) 0.002(0.002) -0.2 -1.0 - Itacimirim, BA 7 1 2 0.44(0.11) 0.001(0.001) 0 0.9 - 1 1 2 1(0.5) 0.002(0.003) 0 0 - B.T.Santos, BA 5 16 4 0.8(0.09) 0.01(0.008) 1.2 4.4 - - - - - - - - - Caramuanas, BA 7 6 4 0.58(0.14) 0.003(0.002) -0.8 0.7 - - - - - - - - - T. Boipeba, BA 9 6 3 0.63(0.06) 0.003(0.002) -0.9 2.2 - - - - - - - - -
P. Seguro, BA 4 1 2 0.25(0.18) 0.0004(0.00) -1.1 -0.9 - 3 6 3 0.8(0.12) 0.006(0.004) 1.3 1.9 - P. Leste, BA 5 3 3 0.38(0.18) 0.002(0.001) -0.5 0.3 - - - - - - - - - P. Lixa, BA 5 2 3 0.62(0.14) 0.001(0.001) 0.02 -0.2 - - - - - - - - - P. Sul, BA 2 2 2 0.67(0.2) 0.002(0.002) 1.89 1.5 - 2 6 3 0.83(0.22) 0.007(0.005) 1.7 1.1 - P. Abrolhos, BA 6 1 2 0.48(0.1) 0.001(0.001) 0 1 - - - - - - - - - C. Frio, RJ 8 2 3 0.57(0.11) 0.001(0.001) 0 0.3 - - - - - - - - - Total 76 46 24 0.78(0.02) 0.007(0.004) -1.6* -4.27 0.03* 38 40 36 0.93(0.02) 0.007(0.004) -1.5* -23.8* 0.01* CAG – 227 bp S. siderea S. radians Panamá - - - - - - - - - - - - - - - - Titanzinho, CE - - - - - - - - 2 2 2 0.66(0.2) 0.01(0.01) 1.9 1.5 - A. Rocas 1 0 1 0 0 0 0 - 4 4 2 0.53(0.2) 0.01(0.01) 1.8 3.2 -
P.Búzios, RN - - - - - - - - 5 0 1 0 0 0 0 - Pernambuco - - - - - - - - - - - - - - - - S.J. Milagres, AL - - - - - - - - 2 0 1 0 0 0 0 Coruripe, AL - - - - - - - - - - - - - - - - Itacimirim, BA 5 8 3 0.6(0.13) 0.01(0.01) 0.16 3 - - - - - - - -
B.T.Santos, BA - - - - - - - - - - - - - - - -
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Caramuanas, BA 5 5 5 0.82(0.09) 0.01(0.01) -0.33 -1.08 - - - - - - - -
T. Boipeba, BA 4 0 1 0 0 0 0 - - - - - - - - -
P. Seguro, BA 4 0 1 0 0 0 0 - - - - - - - - -
P. Leste, BA 4 2 3 0.71(0.12) 0.004(0.003) 0.41 -.07 - - - - - - - - -
P. Lixa, BA 5 1 2 0.53(0.17) 0.002(0.003) 0.85 0.63 - - - - - - - - - P. Sul, BA - - - - - - - - - - - - - - - - P. Abrolhos, BA 4 4 2 0.43(0.17) 0.01(0.01) 0.48 3.15 - - - - - - - - -
C. Frio, RJ 5 3 4 0.8(0.09) 0.01(0.004) -0.6 -0.42 - - - - - - - - - Total 34 14 11 0.76(0.04) 0.01(0.01) -1.2 2.8 0.2 12 4 2 0.54(0.12) 0.01(0.01) 1.7 3.7 0.7 SRP – 54 233 bp S. siderea S. radians Panamá - - - - - - - - - - - - - - - - Titanzinho, CE - - - - - - - - - - - - - - - - A. Rocas 2 0 1 0 0 0 0 5 38 5 0.82(01) 0.08(0.05) 2.14 6.3 - P.Búzios, RN - - - - - - - - 5 4 6 0.84(0.1) 0.007(0.005) 0.38 -2.5* - Pernambuco - - - - - - - - 3 3 3 0.8(0.12) 0.007(0.006) 1.12 0.62 - S.J. Milagres, AL - - - - - - - - 4 2 2 0.57(0.1) 0.005(0.004) 1.79 2.22 - Coruripe, AL - - - - - - - - 2 3 3 0.83(0.22) 0.008(0.007) 1.09 0.006 - Itacimirim, BA 7 38 5 0.83(0.06) 0.08(0.04) 1.97 9.35 - - - - - - - - - B.T.Santos, BA 5 33 4 0.73(0.12) 0.07(0.04) 2.05 9.1 - - - - - - - - - Caramuanas, BA 6 36 6 0.81(0.1) 0.05(0.03) -0.43 3.42 - - - - - - - - - T. Boipeba, BA 4 1 2 0.42(0.07) 0.002(0.002) 0.33 0.53 - - - - - - - - - P. Seguro, BA 4 32 3 0.71(0.12) 0.08(0.04) 2.4 9.25 - - - - - - - - - P. Leste, BA 5 34 5 0.82(0.1) 0.07(0.04) 1.96 5.77 - - - - - - - - - P. Lixa, BA 2 1 2 0.5(0.27) 0.002(0.003) -0.61 0.17 - - - - - - - - - P. Sul, BA 1 0 1 0 0 0 0 - - - - - - - - - P. Abrolhos, BA 6 42 7 0.88(0.8) 0.09(0.05) 1.5 4.16 - - - - - - - - - C. Frio, RJ 7 4 4 0.58(0.14) 0.006(0.004) 0.02 0.1 - - - - - - - - - Total 49 52 22 0.79(0.03) 0.07(0.03) 0.8 4.8 0.05 19 38 12 0.87(0.3) 0.05(0.2) 0.61 3.4 0.2
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Table 3. Population pairwise ΦST for ITS, CAG and SRP54, respectively. S. siderea is below the diagonal and S. radians is above the diagonal. * = statistically significant values (p<0.05).
Localities 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17
ITS – 573 bp 1-Panamá 0 0.82* 0.63* 0.55* 0.74* 0.58* 0.84* 0.89* - - - 0.84* - - 0.71* - - 2-Titanzinho, CE - 0 0.44* 0.54* 0.89* 0.55* 0.77* 0.89 - - - 0.80* - - 0.48* - - 3-A. Rocas 0.60* - 0 0.32* 0.68* 0.46* 0.62* 0.46* - - - 0.62* - - 0.34* - - 4-P. Búzios, RN - - - 0 0.64* 0.40* 0.65* 0.52 - - - 0.64* - - 0.40* - - 5-Pernambuco - - - - 0 0.38* 0.67* 0.87* - - - 0.81* - - 0.66* - - 6-S.J. Milagres, AL - - - - - 0 0.39* 0.27 - - - 0.51* - - 0.26 - - 7-Coruripe, AL 0.52* - 1.00* - - - 0 0.82 - - - 0.78* - - 0.51* - - 8-Itacimirim, BA 0.61* - 0.80* - - - 0.49 0 - - - 0.54 - - 0.43 - - 9-B.T.Santos, BA 0.37* - 0.29* - - - 0.03 0.43* 0 - - - - - - - 10-Caramuanas, BA 0.58* - 0.51* - - - 0.10 0.01 0.37 0 - - - - - - - 11-T. Boipeba, BA 0.61* - 0.44 - - - 0.11 0.06 0.38 0.07 0 - - - - - - 12-P. Seguro, BA 0.56* - 0.92* - - - 0.81* 0.14 0.39 0.06 0.18 0 - 0.59 - - 13-P. Leste, BA 0.57* - 0.74* - - - 0.51* 0.16 0.41* 0.10 0.19* -0.02 0 - - - - 14-P. Lixa, BA 0.62* - 0.65* - - - 0.21 0.50* 0.32* 0.31* 0.16* 0.67* 0.57* 0 - - - 15-P. Sul, BA 0.58* - 0.67* - - - 0.11 0.60* 0.22 0.35* 0.26* 0.71* 0.58* 0.33* 0 - - 16-P. Abrolhos, BA 0.59* - 0.78* - - - 0.41 -0.08 0.39 0.00 0.03 0.18* 0.17* 0.45* 0.56* 0 - 17-C. Frio, RJ 0.61* - 0.68* - - - 0.24 -0.03 0.42* 0.03 0.03 0.17 0.18* 0.37* 0.48* -0.05 0 CAG – 227 bp 1-Panamá 0 - - - - - - - - - - - - - - - - 2-Titanzinho, CE - 0 0.32* 0.87* - 0.77* - - - - - - - - - - - 3-A. Rocas - - 0 0.31 - 0.11 - - - - - - - - - - - 4-P.Búzios, RN - - - 0 - 0 - - - - - - - - - - - 5-Pernambuco - - - - 0 - - - - - - - - - - - 6-S.J. Milagres, AL - - - - - 0 - - - - - - - - - - - 7-Coruripe, AL - - - - - - 0 - - - - - - - - - - 8-Itacimirim, BA - - 0.21 - - - - 0 - - - - - - - - - 9-B.T.Santos, BA - - - - - - - 0 - - - - - - - -
10-Caramuanas, BA - - 0.54* - - - - 0.19* - 0 - - - - - - -
11-T. Boipeba, BA - - 1.00* - - - - 0.23 - 0.58* 0 - - - - - -
12-P. Seguro, BA - - 1.00 - - - - 0.25* - 0.38* 1.00* 0 - - - - -
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13-P. Leste, BA - - 0.87 - - - - 0.26* - 0.36* 0.83* 0.20 0 - - - - 14-P. Lixa, BA - - 0.76* - - - - 0.12 - 0.16 0.57* 0.09 0.15 0 - - - 15-P. Sul, BA - - - - - - - - - - - - - 0 - - 16-P. Abrolhos, BA - - 0.54 - - - - 0.06 - 0.28* 0.14 0.38* 0.36* 0.14 - 0 - 17-C. Frio, RJ - - 0.73* - - - - 0.16 - 0.37* 0.19* 0.29* 0.30* 0.12* - 0.08 0 SRP – 54 233 bp 1-Panamá - - - - - - - - - - - - - - - - - 2-Titanzinho, CE - 0 - - - - - - - - - - - - - - - 3-A. Rocas - - 0 0.49* 0.42* 0.47* - - - - - - - 0.37 - - 4-P.Búzios, RN - - - 0 0.05 0.28* - - - - - - - -0.08 - - 5-Pernambuco - - - - 0 - 0.42* - - - - - - - 0.11 - - 6-S.J. Milagres, AL - - - - - 0 - - - - - - - - 0.04 - - 7-Coruripe, AL - - - - - - 0 - - - - - - - - - - 8-Itacimirim, BA - - 0.34 - - - - 0 - - - - - - - - - 9-B.T.Santos, BA - - 0.41* - - - - -0.07 0 - - - - - - - - 10-Caramuanas, BA - - -0.05 - - - - 0.21* 0.26* 0 - - - - - - - 11-T. Boipeba, BA - - 0.02 - - - - 0.42* 0.50* 0.04 0 - - - - - - 12-P. Seguro, BA - - 0.30 - - - - -0.08 -0.10 0.14* 0.41* 0 - - - - - 13-P. Leste, BA - - 0.99* - - - - 0.19 0.19 0.70* 0.99* 0.30 0 - - - - 14-P. Lixa, BA - - 0.17 - - - - -0.02 -0.03 0.05 0.27 -0.10 0.40 0 - - - 15-P. Sul, BA - - 0.00 - - - - 0.24 0.30 -0.23 -0.17 0.15 0.99 0.02 0 - - 16-P. Abrolhos, BA - - 0.25 - - - - -0.05 -0.05 0.14* 0.34* -0.09 0.25 -0.06 0.12 0 - 17-C. Frio, RJ - - 0.03 - - - - 0.49* 0.58* 0.10 0.15* 0.50* 0.96* 0.37 -0.13 0.43* 0
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Figure 6. Mantel test for Siderastrea radians and S. siderea using the three molecular markers ITS, CAG and SRP54. The p-value and R² of each analysis are indicated in the graphs.
Demographic analysis
Tajima‘s D, Fu‘s FS and mismatch distribution analysis results for the ITS
dataset indicated demographic expansion for S. radians, while only the first showed
demographic expansion for S. siderea. The other markers showed no sign of
expansion for any species (Table 2, Figure 7). The coalescent EBSP analyses
presented a signal of demographic variation only for S. radians when ITS sequences
were analyzed, indicating an expansion that started at ~2 Ma (Figure 8 and 9).
Figure 7. Mismatch distribution analysis for Siderastrea radians and S. siderea using the three molecular markers ITS, CAG and SRP54.
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Figure 8. The demographic analysis Extended Bayesian Skyline Plot for Siderastrea siderea for all markers together and for each marker separately. Median shown in black line and the 95% HPD interval shown in gray line.
Figure 9. The demographic analysis Extended Bayesian Skyline Plot for Siderastrea radians for all markers together and for each marker separately. Median shown in black line and the 95% HPD interval shown in gray line.
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Morphometry
In the morphometric analysis, we used a total of 65 samples from our study
and one individual reported by Neves (2004) (Table 4). PCA showed high variation
for the characteristics measured (Figure 10). The PC1 axis explained 47.11% of the
variation and was primarily related to the characteristic Dcor, EspTec, DistCor, and
Nsep (R = -0.50, -0.50, -0.45, -0.42, respectively). The PC2 axis explained 20% of
the variation and was primarily linked to Dcol and Prof (R= - 0.76 and - 0.44,
respectively). The scatterplot (Figure 10 – A (1)) showed high overlap among
localities, although some of them display divergent morphologies. Colonies from B. T.
Santos presented high values for Dcor, Nsep, EspTec, DistCor, but low values for
Prof and Dcol. In turn, colonies from C. Frio also exhibited high values, but mainly for
Prof and Dcol. The morphology of S. siderea (Neves 2004) was very different;
however, it was closer to colonies from B. T. Santos. Pictures of the morphological
variation evidenced in PCA can be observed in Figure 10 - B.
When the genetic groups of each marker were highlighted in PCA, (Figure 10
– A: 2, 3, 4), we observed that S. siderea ITS samples have higher values for each
trait compared to S. radians, although some overlap was identified (Figure 10 – A: 2)
. The CAG samples grouped in Cluster 1 exhibited predominantly low values, while
Cluster 2 individuals have higher ones, also with some overlap (Figure 10 – A: 3) .
For SRP54, we only have available samples from Cluster 1, which did not show a
predominant pattern, instead appearing quite dispersed (Figure 10 – A: 4). Figure 10
– B illustrates corallites of 15 colonies measured and analyzed in PCA. This figure
shows the high variability found in Siderastrea. Colonies cf4, cf3 and co6 are
identified by ITS as S. siderea. Colonies rn8, rn5, co2, rn2, tit6, cor3 are identified by
ITS as S. radians. The others, bts2, car2, ita9, bts8, sjm3 and ps6 did not have the
genetic identification accessed.
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Figure 10. Morphological results. (A) Principal Components Analysis performed with six morphological traits of sampled colonies. Each point in the graph represents a colony. In (1), the graph is colored by localities, and acronyms represent corallites illustrated in B; in (2) the graph is colored by ITS groups; in (3) the graph is colored by CAG clusters of BAPS; in (4) the graph is colored by SRP54 clusters of BAPS. (B) Photography of corallites from different colonies with different morphology. They are indicated in A – 1. The acronym indicates the locality and the number of the individual: cf = Cabo Frio; co = Coruripe; rn = Rio Grande do Norte/P. Búzios; bts = Bahia de Todos os Santos; ita = Itacimirim; sjm = S.J. Milagres; ps = P. Seguro.
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Table 4. Mean, standard deviation and amplitude of morphometric measures for
localities that we have skeletal samples. corallite diameter (corD), columellar
diameter (colD), septal number (sepN), thecal thickness (tecThick), columellar depth
(depth), and the average distance between adjacent sampled calices (corDist). Metric
values in millimeters.
Discussion
This study provided information about the genetic and morphological
diversity of siderastreids along the Brazilian coast, raising unexpected questions
about the systematics of this complex group and suggesting a hypothesis about how
the geographic history of the coast influenced the diversification of its current
lineages. The results are based on an extensive data set including 16 sampling
points along approximately 3000 km of the coast and additional information compiled
from the literature. Despite some efforts, there are few molecular studies of Brazilian
scleractinians with the approach and the amount of data we used here (Neves et al.
2008, Nunes et al. 2009, 2011, Peluso et al. 2018). Therefore, our study will
contribute to the knowledge about the formation of Brazil‘s peculiar marginal reefs
and highly endemic coral fauna.
Localities Dcor Dcol Nsep EspTec Prof DistCor
Titanzinho, CE 3.5 ± 0.38 (3 - 3.8)
0.4 ± 0.04 (0.3 - 0.4)
35.8 ± 2.5 (34 - 39)
0.4 ± 0.07 (0.4 - 0.6)
1.1 ± 0.06 (0.4 - 0.6)
0.9 ± 0.2 (0.8 - 0.9)
P. Búzios, RN 3.7 ± 0.77 (30 - 4.9)
0.5 ± 0.04 (0.4 - 0.5
34.2 ± 8.45 (26 - 42)
0.4 ± 0.09 (0.3 - 0.6)
1.2 ± 0.36 (0.7 - 1.6)
0.8 ± 0.14 (0.7 - 1)
S.J. Milagres, AL 3.3 ± 0.46 (2.9 - 4.1)
0.3 ± 0.1 (0.2 - 0.5)
36.1 ± 4.8 (29 - 41)
0.5 ± 0.06 (0.4 - 0.5)
1.2 ± 0.25 (1 - 1.7)
0.9 ± 0.12 (0.8 - 1.1)
Coruripe, AL 3.1 ± 0.19 (2.9 - 3.3)
0.3 ± 0.05 (0.3 - 0.4)
35.3 ± 1.13 (3.4 - 3.7)
0.4 ± 0.05 (0.4 - 0.5)
1.1 ± 0.15 (1 – 1.3)
0.8 ± 0.15 (0.7 - 1.1)
Itacimirim, BA 3.4 ± 0.35 (27 - 38)
0.5 ± 0.13 (0.4 - 08)
35.8 ± 4.46 (26 - 40)
0.5 ± 0.07 (0.4 - 0.6)
1.2 ± 0.16 (0.9 - 1.3)
1.0 ± 0.13 (0.8 - 1.2)
P. Seguro, BA 3.1 ± 0.31 (2.8 - 3.8)
0.3 ± 0.04 (0.3 - 0.4)
40.5 ± 5.21 (31 - 46)
0.4 ± 0.04 (0.3 - 0.5)
1.0 ± 0.13 (0.9 - 1.3)
0.9 ± 0.11 (0.7 - 1)
B.T. Santos, BA 3.8 ± 0.69 (2.7 - 4.6)
0.4 ± 0.05 (0.3 - 0.4)
46.1 ± 7.86 (33 - 51)
0.5 ± 0.11 (0.3 - 0.6)
1.2 ± 0.16 (1 - 1.4)
1.0 ± 0.3 (0.6 - 1.5)
Caramuanas, BA 3.3 ± 0.44 (2.7 - 4.2)
0.4 ± 0.04 0.3 - 0.4)
42.9 ± 4.73 (38 - 51)
0.4 ± 0.06 (0.3 - 0.5)
1.2 ± 0.1 (1.1 - 1.4)
0.8 ± 0.12 (0.6 - 1)
C. Frio, RJ 3.8 ± 0.27 (3.5 - 4.4)
0.5 ± 0.04 (0.4 - 0.6)
46.0 ± 3.37 (44 - 57)
0.4 ± 0.06 (0.3 - 0.6)
1.6 ± 0.58 (1 - 2.5)
0.8 ± 0.14 (0.6 - 1)
*S. siderea, Panamá (Neves 2004)
4 0.4 50 1 2 1.8
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Systematics considerations
The evidence of two genetic groups of Siderastrea along Brazilian coast
evidenced by ITS sequences suport other studies of the literature (Neves et al. 2008,
Nunes et al. 2011). However, the molecular comparison of our ITS sequences with
the results of Forsman et al. (2005) indicates that the two genetic groups are very
similar to the species Siderastrea radians and S. siderea described from the
Caribbean and indicate no evidence of the third species, S. stellata, considered
endemic of our coast.
These results support in part Neves et al. (2008), the first genetic study to
define the occurrence of two genetic groups of Siderastrea for Brazil and not one, as
previously thought. Our data agree with the occurrence and distribution of the two
groups and with the record of S. radians for the Brazilian coast. However, our
comparison with Caribbean samples identified the other group as S. siderea, while
Neves and colaborators identified them as S. stellata. Neves et al. (2008) identified
the species using morphological information; but they did not provide a genetic
comparison with species from the Caribbean, leaving one gap in their work.
A very similar result to what we found for ITS was reported by Nunes et al.
(2011) when they used the nuclear molecular markers β-tubulin and Pax-C to study
dispersion and connectivity in Amphi - Atlantic corals, including Siderastrea. The
authors pointed out that Brazilian siderastreids collected in three points along ~3000
Km of Brazilian coast were very similar to species from Panamá (in the Caribbean)
and also denominate then as S. radians and S. siderea. They found evidence of
hybridization and suggested that it could correspond to S. stellata; but they did not
address this issue more deeply. Therefore, studies that used nuclear genetic markers
up to the present day, including our and other works, have not indicated species
differentiation of a third species of Siderastrea on the Brazilian coast.
On the other hand, our morphological results showed some differentiations
between Brazilian and Caribbean species. While the Brazilian individuals genetically
identified here as S. radians had considerable correspondence with taxonomical
morphs, the samples genetically identified as S. siderea had a discrepant
morphology when compared with the original diagnosis and with specimens from the
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Caribbean (Neves 2004) (Figure 1 and 8). Individuals collected here present small
and irregular corallites and intratentacular budding, known as corresponding to the
description of S. stellata, as can be seen in Figure 8 and Table 3 (Neves et al. 2010).
Thus, we also detected different morphotypes in Brazil, as proposed by other authors
(Vaughan 1919, Neves et al. 2010), despite the genetic similarity with the Caribbean
species.
Incongruences among morphological and genetic data in scleractinian
species are very common in the literature. They are usually explained by high
phenotypic plasticity, incomplete lineage sorting, hybridizations and combinations of
these factors (Forsman et al. 2009, Budd et al. 2010). In the case of Atlantic
Siderastrea, factors suggested as reasons for speciation between groups from the
Caribbean and Brazil, such as environmental differences, the Amazon River
geographical barrier and/or just spatial distance could be important for morphological
differentiation, or to induce genetic structure between the regions as observed by
Nunes et al. (2011). Nevertheless, they were probably not sufficient to promote a
complete speciation on the Brazilian coast. Indeed, new records of Siderastrea in
mesophotic communities of the Amazon river mouth (Cordeiro et al. 2015) suggest
that this barrier to dispersion could be less effective than was expected, mainly for
this group.
Recently, a molecular and morphologic study of Siderastrea using samples
restricted to Veracruz Reef System National Park reported individuals similar to S.
stellata (Gulf of México; García et al. 2017). The molecular analysis of this study was
based on two ITS nuclear regions. When they used the same ITS region used in our
work, they defined all samples as S. radians. When they used the ITS2 region, they
observed three well-defined genetic groups with congruence with the morphology of
the three species S. siderea, S. radians and S. stellata. Given the high phenotypic
plasticity and dispersal ability observed for Atlantic Siderastrea (Neves et al. 2008,
Neves et al. 2010, Nunes et al. 2011), the occurrence of S. stellata–like morphotypes
in Mexico is reasonable.
CAG and SRP54 sequences could not be compared to Caribbean samples
because we do not have data from this region; however, these markers added
intriguing data to our study. The lack of monophyly among groups and little
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54
congruence with both the ITS dataset and morphological identification (Figure 1, 2, 3
and 10) suggest two possibilities. First, the incongruence among markers could
indicate incomplete lineage sorting, a common pattern that was also suggested for
other species of corals (Willis et al. 2006). Second, it might indicate the existence of
hybridization and/or introgression among species. Hybridization and introgression
were confirmed for many broadcast-spawning corals such as S. siderea (van Oppen
et al. 2000, Vollmer and Palumbi 2002, Arrigoni et al. 2016, Hellberg et al. 2016).
However, this process has few records in brooding corals such as S. radians, and it
was only reported for Madracis, Pocillopora and Styllopora (Miller and Ayre 2004,
Flot et al. 2008, Frade et al. 2010).
Our molecular dating indicated a divergence between S. radians and S.
siderea in the late Oligocene (Figure 1), which makes the incomplete lineage sorting
hypothesis less probable, although this alternative cannot be ruled out. In turn, S.
radians and S. siderea are sibling species with sympatric and syntopic occurrence
(Figure 5); thus, hybridization between the species is plausible, although no
ecological experiments have demonstrated it so far. Both hybridization and
incomplete lineage sorting are in agreement with the high morphological variation
observed in Brazilian siderastreids and could explain the morphological overlaps
between S. radians and S. siderea (Figure 10), commonly discussed in the literature
(Yonge 1935, Foster 1980, Zlatarski and Estalella 1982, Menezes et al. 2013, 2014).
All of this information highlights the importance of a wide taxonomic revision
of Atlantic siderastreids. Our data also indicate the need to take into account the
proximity between S. siderea and S. stellata. Forsman et al. (2005) proposed a close
relationship between S. radians and S. stellata based on one sample from
Pernambuco, on the northeastern coast of Brazil, were S. radians is predominant.
However, at that time, they did not know about the occurrence of two species in
Brazil, and they treated S. stellata as the only and endemic species of our coast. The
inclusion of broad sampling throughout the Atlantic Ocean will also help to better
understand the taxonomy and geographical distribution of these lineages.
Siderastrea has a wide distribution in the Atlantic Ocean and most molecular studies
include too few points. In the Central Atlantic, for example, studies are usually
centered on Panamá. Finally, the use of cutting-edge molecular methods, including
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next-generation sequencing and advanced analysis techniques, associated with
micro and macro morphological structures, could also help to clarify these taxonomic
difficulties.
Phylogeographic patterns
Time-calibrated analysis indicated that the divergence between the two
genetic groups found on the Brazilian coast, S. radians and S. siderea, occurred at
~29.02 Ma (95% HPD = 15.6-59.8 Ma) (Figure 4). Several studies suggest that,
during this period, the earth was undergoing important environmental transitions due
to tectonic and climatic events (Potter and Szatmari 2009, Smart and Murray 1994).
In the Atlantic Ocean, studies indicate that an increase in regional planktonic
productivity would have increased due to continental shelves‘ progradation (Smart
and Murray 1994, Edinger and Risk 1995), changes in ocean temperature and
circulation (Nisancioglu 2003) and sea level fluctuations (Rossetti et al. 2013).
According to Budd (2000), who analyzed Caribbean fossil coral reefs, the Late
Oligocene to Earliest Miocene (28 ± 24 Ma) is one of the five known periods of
extinction followed by diversification in Caribbean coral reefs. This information
supports the idea that the genetic groups found in our study may have emerged
during this period. However, it is difficult to indicate which of the various
environmental and geological events caused this differentiation based only in our
data.
The predominance of S. radians in the north and S. siderea in the south
along Brazilian coast, with sympatric and syntopic occurrence in some places, was
also observed in other studies with siderastreids (Neves et al. 2008). Other marine
groups also indicate the presence of this barrier (Souza et al. 2017, Picciani et al.
2017), although it is not a rule (Peluso et al. 2018). This pattern has been attributed
to the drainage of the São Francisco River, which causes a salinity and sediment
barrier on the coast, and to the anticlockwise oceanic gyre that reaches the Brazilian
shore between 8ºS and 10ºS and bifurcates, forming the Brazilian Current to the
south and the Northern Brazilian Current to the north (Carvalho and Kikuchi 2013).
Other evidences are necessary to associate these events with Siderastrea
diversification, but these events apparently limited the distribution of S. radians and
S. siderea and indicate a niche differentiation between them. It is possible that S.
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radians individuals hardly crossed the São Francisco barrier and that they develop
better in higher temperatures of low latitudes, while S. siderea could tolerate the
lower temperatures that occur from the resurgence of the Central Waters of the
South Atlantic at approximately 22º S, near Arraial do Cabo (Stramma and England
1999, Neves 2004).
Regarding intraspecific variation, the results showed absence of diversity
gradients or areas with higher variability. Consequently, we detected no signs of
recent colonization from the Caribbean, as observed for other marine organisms
(Rocha 2003, Souza et al. 2017); or from possible Pleistocene coral reef refugia in
submerged seamounts near Abrolhos Bank, as hypothesized by (Leão 1983) and
evidenced by recent results with other groups (Pinheiro et al. 2017, Peluso et al.
2018). However, these data agree with the possibility that the species may have
maintained their latitudinal amplitude of occurrence during the last sea level
fluctuations.
Stratigraphic studies on different coasts around the world (eg. Gulf of
Mexico and Gulf of Papua) reveal the presence of terraces of coralgal reefs at around
60 and 90 m deep along the slopes of the continental shelf (Droxler and Jorry 2013,
Khanna et al. 2017). According to these studies, the terraces were constructed near
the coast during ―windows of opportunity‖ promoted by punctuated rises in sea levels
since the last glacial maximum. Kikuchi and Leão (1998) described reef structures at
about 80 m deep in Brazil; however, this issue has rarely been explored since. It
could be that the known resistance of siderastreids‘ to environmental variation
(Lirman et al. 2002, Castillo et al. 2014, Horvath et al. 2016) may have favored the
occupation/building of these terraces over time while less resistant corals may have
been restricted to refugia in regions far from the coast, as indicated for Mussismilia
hispida by Peluso et al. (2018). However, further studies are necessary to investigate
the presence of Brazilian terraces and their possible influence on scleractinian
populations during geological time.
Alternative explanations for the absence of diversity gradients in our data
are related to the reproductive traits and ecological population structure of Brazilian
siderastreids. Previous studies suggest that, despite the brooding behavior of both
Brazilian species, which favors structure by phylopatric settlement (i.e., offspring
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grow near to progenitor colonies), moderate gene flow has been observed for both
species (Neves et al. 2008, Nunes et al. 2011). Neves and Silveira (2003) also
described that larvae of S. stellata could remain approximately 15 days in the water
column, facilitating migration between distant populations. These factors could
promote genetic homogeneity along the coast and decrease differences among
localities. Additionally, the probable presence of colonies with different ages in our
samples due to indeterminate growing of corals could mask a possible spatial genetic
structure. The attempt to standardize colony sizes as an age estimate is imprecise
since coral can usually fuse, fractionate or undergo partial mortality (Sebens 1982).
However, this cohort overlap is inherent in most coral populations and present in
most studies (Veron 1995).
The occasional occurrence of a different group of S. siderea in B. T. Santos
and Panamá (Figure 5) is intriguing. An introduction event of a different S. siderea
genetic group could perhaps explain this isolation. B. T. Santos has ~1200 km2 of
calm waters and is known for the presence of important vectors of invasion, such as
three commercial ports, oil platforms, anchorage points and intense ship traffic ever
since the great navigations in the 16th century (Amado-Filho et al. 2008). The
literature describes some exotic species in this bay (Gerhardinger et al. 2006,
Almeida et al. 2015), with recent reports of invasive corals (Tubastraea tagusensis
and Tubastraea coccinea - (Sampaio et al. 2012). Considering the high resistance of
Siderastrea and the presence of incrusting forms, the introduction of a different
genetic group of S. siderea cannot be ruled out.
The demographic analyses for all markers together have not indicated
recent expansion since the Last Glacial Maximum, and this agrees with the
hypothesis that siderastreids may have followed the displacement of the sea level
over this time, keeping their latitudinal range. However, the demographic analysis
using only ITS shows that S. radians indicated demographic expansion since early
Pleistocene, while the demography of S. siderea has remained constant. The
probable distinct ecological niches between species may have influenced these
contrasting results. While S. radians is more restricted to shallow and warm water
(Laborel 1969, Neves 2004), S. siderea has eurybathic and eurythermic distribution
(Laborel 1969/70, Lirman et al. 2002, Castillo et al. 2014, Horvath et al. 2016,
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Cordeiro et al. 2015). Shallow regions, where S. radians is frequent, are much more
vulnerable to geologic events such as sea level changes (Karhng et al. 2010,
Lindfield et al. 2016, Bongaerts et al. 2017), which may be reflected in the higher
population fluctuation over time.
Conclusion
Our study indicated that Brazilian siderastreids are very similar to their
Caribbean congeners S. siderea and S. radians, suggesting that S. stellata could
represent a morphological variation of S. siderea. The genetic diversity, structure and
demography of both species showed no evidence of recent colonization from the
Caribbean or dispersion from a possible Pleistocene refuge in submerged seamounts
near Abrolhos Bank, which suggests that Siderastrea species may have maintained
their latitudinal amplitude of occurrence during sea level fluctuation over geological
time. Indeed, new stratigraphic evidence of deep coralgal terraces on the slopes of
continental shelf‘s seems to support this hypothesis. We highlight the need for a
taxonomical revision of this group using wide genetic and morphological sampling
throughout the Atlantic Ocean and further investment in more polymorphic markers to
confirm the biogeographic pattern found. This study contributes to the knowledge
about the historical process responsible for the distribution of current Brazilian
marginal coral reef biodiversity.
Acknowledgements
We thank Prof. Dr. José Roberto Trigo (Laboratório de Ecologia Química –
UNICAMP) for lending photography equipment. We thank Prof. Dr. Ruy K. P. Kikuchi
(Laboratório de Recifes de Corais e Mudanças Globais – RECOR) for help with
logistical support for Abrolhos fieldwork. We are grateful to the team of Laboratório
de Diversidade Genética at UNICAMP, Fernanda Fontes, Cecília Fiorini, Jair
Mendes, Luiz Bartoleti, Thadeu Sobral-Souza, Priscila Madi, Felipe Roberto, Beatriz
Pereira, Lívia Zuffo, Gustavo Pugliese, Wendy Arroyo and João Claudio, for help with
suggestions and discussions. We thank Prof. Dr. Kenneth Johnson (Natural History
Museum, London) for invaluable help with fossil information for the study. We thank
Prof. Dr. Liana Mendes, Aline Medeiros (Universidade Federal do Rio Grande do
Norte), Bárbara Pinheiro (Universidade Federal de Pernambuco), Prof. Dr. Cláudio
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59
Sampaio (Universidade Federal de Alagoas), Prof. Dr. Igor Cruz (Universidade
Federal da Bahia), José de Anchieta, Ricardo Miranda, Miguel Loiola, Lua Porto,
Thiago Albuquerque, Adriano Leite and José Amorim, for outstanding help in the
fieldwork. We also acknowledge the following entities for financial support:
Coordenação de Aperfeiçoamento de Pessoal de Nível Superior for research grant;
Conselho Nacional de Desenvolvimento Científico e Tecnológico - CNPq (311763-
2014-6); São Paulo Research Foundation – FAPESP (201308293-7).
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CAPÍTULO II
Paleoclimatic distribution and phylogeography of Mussismilia braziliensis (Anthozoa; Scleractinia), and endemic coral of Brazilian reefs
Abstract
Several studies suggest that Pleistocene glacial cycles and sea level
variations drastically affected shallow and near shore ecosystems such as coral
reefs. For the Southwest Atlantic, a submarine mountain chain near Abrolhos Bank
has been proposed as a region of climatically stable refugia during the Last glacial
Maximum (LGM), from where our present Brazilian reefs received propagules. Here,
we integrated Paleoclimatic simulations based on ecological niche models (ENM)
and a phylogeographic approach to access this hypothesis for the endemic and
important reef building coral Mussismilia braziliensis. The niche modeling indicated a
reduction in the potential distribution of this species from present to LGM; however,
contrary to what was expected, the predicted climatically stable regions were not
located in the Victoria – Trindade mountain chain, but in regions to the north of this
chain, where the species currently occurs. Genetic data showed low structure for the
three markers used, SRP-54, ITS and MaSC-1, and no sign of recent demographic
expansion. Our results suggested a scenario where M. braziliensis probably followed
the sea level variation, maintaining the amplitude of its latitudinal distribution since
LGM, and was not confined to a reduced climatic refugium as previously imagined.
We highlight the pioneering nature of this study in trying to comprehend the historical
processes related to the formation of the current scleractinian biodiversity in Brazilian
reefs.
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Introduction
Several works suggest that glacial cycles occurred throughout the Pleistocene
(2.5 Ma – 11 thousand years before present) and caused important changes in the
marine ecosystems (Ludt and Rocha 2014). There are signs that these events may
have altered ocean currents, changed water column thermal dynamics and modified
sea level (which dropped as much as 120 m during the Last Glacial Maximum - LGM)
affecting shallow and near-shore ecosystems such as coral reefs (Molengraaff and
Weber 1937, Benzie 1999, Veron 1995, Pellissier et al. 2014, Ludt and Rocha 2014,
Renema et al. 2016). Few pleistocenic extinctions have been reported for marine
organisms, in comparison with other past geological periods (Ludt and Rocha 2014);
however, some authors indicate that this period had one of the highest extinction
rates of scleractinian corals in the Mid-Atlantic Ocean (Budd 2000, Johnson et al.
1995).
Some coral reef habitats have been pointed out as refugia based on their
climate stability during the Pleistocene (Ludt et al. 2012, Pellissier et al. 2014).
Refugia may be defined as habitats that provide shelter from environmental stressors
or advantages in biotic interactions, permitting a local long-term persistence of
populations (Tzedakis et al. 2013, Keppel et al. 2012, Gavin et al., 2014, Kavousi and
Keppel 2017). Refugia have an important role in avoiding species extinction, acting
as bases for the recolonization of more unstable areas and allowing enough time to
generate areas with a high diversity (McKenna and Farrell 2006; Carnaval et al.
2009; Pellissier et al. 2014b). Evidence of refugia in the Indo – Pacific ocean have
been of great importance in explaining the current pattern of reef diversity (Ludt et al.,
2012, Bowen et al., 2013, Cowman et al. 2017).
For the South Atlantic ocean, where reef formations extend mainly in a north-
south direction along ~3000 Km of Brazilian coast (Leão et al. 2003), the influence of
Pleistocene climatic oscillations on coral diversity is still poorly explored (Leão 1983,
Peluso et al. 2018). This region is known for its narrow continental shelf (an average
width of 50 km) and turbid waters because of riverine water drainage, coastal erosion
and sediment re-suspension (Leão and Dominguez 2000, Castro and Pires 2001,
Leão et al. 2003, Segal et al. 2008). Zooxantellate corals have low species richness,
with 21 species described; however, these regions have a remarkable endemism rate
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(Neves et al. 2006). Additionally, the predominance of ancient massive morphs, in
spite of the more recent porous and branched morphology known in Caribbean
Acroporids (Pandolfi and Jackson 2006), is an interesting feature of Brazilian
species.
Some authors proposed that the presence of archaic morphs preserved on the
Brazilian coast occurs because of the existence of a refugium near Abrolhos Bank
during the low sea level in the Pleistocene (Leão 1983, Nunes et al. 2008). This
region is known for its enlargement of the continental shelf (~200 km width) and for
the presence of the Vitória - Trindade submarine mountain chain away from and
perpendicular to the shoreline (Leão et al. 2003, Pinheiro et al. 2014). According to
those authors, these distant habitats allowed corals to remain protected from coastal
environmental variation (mainly sedimentation) during the Pleistocene glacial periods.
The increase in the sea level caused a displacement of preserved fauna in refugia to
the current continental shelf, and the archaic traits of a tertiary coral fauna were
conserved (Leão 1983). Despite the scientific importance of this hypothesis, there are
few subsequent studies exploring it for corals (Peluso et al. 2018).
The genus Mussismilia is known for massive colonial forms, corallites that are
discrete or arranged in short series, discontinuous columela with trabecular linkage
and abundant vesicular endotheca (Budd et al. 2012). It was considered a member of
the Mussidae Family, but has recently been transferred to the Favinnae Subfamily,
and it is now a sister of groups previously considered Faviidae (Nunes et al. 2008,
Budd et al. 2012, Schwartz et al. 2012). The genus is composed of four living
species, Mussilimila hispida (Verrill, 1901), M. harttii (Verrill, 1868), M. braziliensis
(Verrill, 1868), M. leptophylla (Verrill, 1868) and two extinct species registered in the
Mediterranean basin, M. provincialis Matheron 1900 and M. vindobonensis Chevalier
1961. Fossils of the living Mussismilia were found along several Mid – Atlantic
deposits during periods known for great environmental changes, such as the
Miocene, Pliocene and early Pleistocene (Budd et al. 1999, Budd 2000, Klaus et al.
2011, 2012). Currently, the genus is locally extinct in this region, but represents a
paleoendemic group of Brazilian reefs (Cowman et al. 2017). Indeed, some
experimental studies indicate that it can adapt well to sediment-dwelling
environments found on the Brazilian coast (Loiola et al. 2013). The endemic
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condition of Mussismilia on the Brazilian coast is an intriguing question and could be
related to the presence of Pleistocene refugia; however, few studies have directly
addressed this issue before (Peluso et al. 2018).
Currently, different approaches of ecological niche modeling (ENM) and
paleoclimatic simulations, based on coupled atmosphere-ocean models (AOGCMs),
such as PMIP3 (Paleoclimate Modeling Interface Project), have been used to assess
the species ranges across space and time and to build a hypothesis about the
influence of past climate change on species diversity. These approaches have been
largely applied to terrestrial taxa explorations to identify Pleistocene climate change
influences on vertebrates and invertebrates (Carnaval et al. 2009b; Peres et al.
2015), detect retraction or expansion of biomes and their old connections (Carnaval
and Moritz 2008, Leite et al. 2016, Sobral-Souza et al. 2015). However, these
approaches have been under-used in studies of the influence of paleoclimate
changes on sea taxa, such as corals.
In addition, phylogeographic methods have used spatial patterns of genetic
polymorphism sampled from present-day populations to infer the evolutionary history
of population dynamics (Avise 2009). Coupled with ENM and paleoclimatic
simulations, this approach can provide a powerful tool to study the diversification
processes that give rise to current populations (Beheregaray 2008, Gavin et al.
2014). In Brazil, some phylogeographic studies showed interesting patterns for
fishes, crustaceans, cnidarians and polychaetes (Stampar et al. 2012, da Silva et al.
2016, Neves et al. 2016, Souza et al. 2016, Nunes et al. 2016, Hurtado et al. 2016,
Peluso et al. 2018).
In this work, we integrated ENM and phylogeographical approaches to
investigate the existence of coral reef refugia around Abrolhos Bank during the
Pleistocene, using Mussismilia braziliensis. This species is called ―the Brazilian brain
coral‖ and is one of the main builder corals at the top of the ―chapeirões‖ (mushroom-
shaped outcrops) of Brazilian reefs (Leão et al. 2003). However, it is confined to a
very restricted zone of ~800 km around Abrolhos Bank, and some evidence shows
that it is currently subject to anthropic and climatic threats (Leão et al. 2008, Francini-
Filho et al. 2008, Garcia et al. 2013, Leão et al. 2016, Mazzei et al. 2016). Our
specific objectives were (1) build ENM predictions to compare the past (LGM – 21ka)
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and the current Mussismilia braziliensis potential distribution, (2) access genetic
diversity and population structure throughout the species‘ geographical distribution,
(3) infer phylogenetic relationships and divergence time among populations (4) and
estimate their demographic history. We hypothesized the existence of Pleistocene
spatial refugia in the submarine mountain chain near Abrolhos Bank, with more
genetic diversity and ancient lineages in reefs from this region, and signs of
demographic reduction in the Pleistocene followed by recent population expansion.
We emphasize that this is the first study that combines Paleoclimatic Modeling and
Phylogeographic approaches to explore the evolutionary history of Brazilian
scleractinian corals.
Material and methods
Present and Paleodistribution models
We used ENM approaches to build the current distribution and the
paleodistribution of Mussismilia braziliensis. Usually, ENM techniques infer
correlations between environmental variables (climate) and current known
occurrence points to predict the environmental conditions tolerated by a species, to
plot suitability values in other locations where the species is not-known (Franklin and
Miller 2010, Peterson et al. 2011). Three major pillars for building ENM are listed: (i)
species occurrence (ii) climate variables and (iii) mathematical algorithms (Peterson
et al. 2011).
We obtained occurrence records of Mussismilia braziliensis in the OBIS
dataset (Ocean Biogeographic Information System - available in
http://www.iobis.org). Also, we included records of our samples in field observation of
M. braziliensis and current records of its recent expansion in distribution (Mazzei et
al. 2016), totalizing 1058 known occurrence points (Supplementary information 1).
The climate and paleoclimate variable layers, used to infer the species
distribution, were downloaded at MARSPEC database (Ocean Climate Layers for
Marine Spatial Ecology available at https://www.marspec.org) (Sbrocco and Barber
2013). This database has 18 sea environmental data items (derived from salinity,
temperature and physical characteristics) for current and past (LGM) scenarios.
However, these variables are auto-correlated and a variable assortment was
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necessary. We chose layers with 5 arc minutes, ~10 km resolution (in the Equator
region), and we clipped them to the Western Atlantic Ocean with an extent of (75º
and 30ºW longitude and 35ºS and 15ºN latitude). We used this background as the
studied area, considering the historical and current species dispersion capability, two
criteria described by Barve et al. (2011) for background selection. We applied a
factorial analysis, with Varimax, to choose variables that vary more throughout the
study area (similar to the strategy adopted by Sobral-Souza et al. 2015). The chosen
variables were Plan curvature (Biogeo3), Profile curvature (Biogeo4), Mean annual
SSS (psu) (Biogeo8), Annual range in SSS (psu) (Biogeo11), SST of the warmest
month (°C) (Biogeo15), Annual range in SST (°C) (Biogeo 16). We included
bathymetry, although it has not been selected in this analysis, because of its
biological importance for coral reef distribution (Veron 1995)
The occurrence points and selected climatic variables were used to build ENM
generated under the current climate scenario and predicted for the 21 Ka (LGM)
climate scenario. We used five mathematical algorithms that are based on different
methods and premises in order to increase the reliability of models based on a
forecast ensemble approach (Araujo and New 2007). Three of them are based only
on presence records: (1) envelope score, Bioclim (Nix 1986); (2) Mahalanobis
distance (Farber and Kadmon 2003) and (3) Domain—Gower distance (Carpenter et
al. 1993); and two are machine-learning methods based on presence/background
records: (4) Support Vector Machines (SVM) (Tax and Duin 2004); and (5) Maximum
Entropy (MaxEnt) (Phillips and Dudík 2008).
We used a bootstrap method to randomize the occurrence points into 75-25%
train-test subsets to evaluate the models. As these subsets are correlated, we
performed the bootstrap procedure 20 times to decrease data co-linearity. We
calculated the ‗maximum sensitivity and specificity threshold‘ for each model to
compute the continuous map in binary maps. We used this threshold because is the
best when using presence-only methods in the ENM approach (Liu et al. 2011,
2013). Based on this threshold value, we also estimated the True Skill Statistic
(TSS), an accuracy measure to evaluate presence–absence distribution models
(Allouche et al. 2006). We considered TSS values higher than 0.5 (Allouche et al.
2006). Finally, we computed a consensual map with the frequency of each grid cell
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predicted from all accurate models (a similar method to that used in (Sobral-Souza et
al. 2015).
Sample collection
We sampled fragments of Mussismilia braziliensis (~5 cm) from five sites
throughout its distribution (Table 1). We used a hammer and chisel to remove them,
taking care to minimize damage to the whole colony. We scraped the fresh tissue
from the living surface, put it in vials of 1.5 ml containing anhydrous alcohol or
guanidine thiocyanate solution (4 M guanidine thiocyanate, 0.1% N-lauroyl sarcosin
sodium, 10 mM Tris pH8, 0.1 M 2-mercaptoethanol) and stored it at freezing
temperature until extraction. All individuals sampled were under permits granted by
the Instituto Chico Mendes de Conservação da Biodiversidade (ICMBio, permit nos.
39090).
DNA extraction, amplification and sequencing
Genomic DNA was extracted using a phenol protocol described by (Nunes et
al. 2009). Three nuclear markers were used. The Signal Recognition Particle 54-kDa
region (SRP54) was amplified using primers SRP54Madfor and SRP54Madrev2
(Frade et al. 2010), and the thermal profile had initial denaturation step at 94°C for 2
min; 35 cycles at 94°C 2min, 52°C for 30 s and 72°C for 1 min; and extension at
72°C for 2 min. The Internal Transcribed Subunit region (ITS) was amplified using
primers ITS-1 and ITS-4 (White et al. 1990), and the thermal profile had an initial
denaturation step at 96°C for 2 min; 35 cycles at 95°C for 10 s, 52°C for 30 s and
70°C for 4 min; and extension at 70°C for 2 min. The MaSC-1 was amplified using
primers 3-550 F and 3-550 R (Macdonald et al. 2011), and the thermal profile had
initial denaturation step at 95°C for 4 min; 35 cycles at 95°C for 45 s, 62°C for 45 s
and 72°C for 2 min; and extension at 72°C for 10 min. All PCR reactions were carried
out with a total volume of 25µl with 10 ng of genomic DNA, 3.0 mM MgCl2, 1X of taq
buffer, 0.4 mM of dNTP, 0.16 µM of each primer, 1U of Taq DNA polymerase and
milli-q water.
The amplicons were analyzed in a Perkin-Elmer Prism 377 capillary
sequencer. Sequences were aligned using the MUSCLE algorithm (Edgar 2004), and
manually edited in MEGA 6.0 (Tamura et al. 2013). Heterozygous sites were coded
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agreeing with IUPAC ambiguity codes. Phased haplotypes were previously estimated
using a Bayesian method employed in PHASE (Stephens and Donnelly 2003), based
on the input files prepared with Dnasp v. 5.0 (Librado and Rozas 2006). The gametic
phases were inferred with a minimum posterior probability of 0.9, usually
recommended to reduce the number of unresolved haplotypes with false positives
(Garrick et al. 2010).
Haplotype networks, genetic diversity and population structure
We constructed haplotype networks in PopART v. 1.77 (Leigh and Bryant
2015), using a Median-joining algorithm (Bandelt et al. 1999). Molecular diversity
indices, haplotype frequencies and pairwise differentiations among sample sites
(ΦST) were calculated using Arlequin v. 3.5 (Excoffier & Lischer, 2010). Isolation-by-
distance was calculated using GeneAlEx v. 6.5 (Peakall and Smouse 2012). An
analysis of molecular variance, AMOVA, with three levels, was conducted to compare
percentage of variance among localities and among regions (North: Itacimirin and
Caramuanas; and South: P. Seguro, P. Leste, P. Abrolhos) using Arlequin v. 3.5.
(Excoffier et al. 1992). We also applied a Bayesian Analysis of Population Structure -
BAPS v. 6.0 (Corander et al. 2008) to estimate the most probable number of genetic
groups in our data (k) in a range between 1 and 20.
Phylogenetic inference and divergence time
We constructed independent Bayesian inference trees for each marker using
BEAST v.1.7.4 (Drummond et al. 2012a). The best fit nucleotide substitution models
selected by Akaike Information Criterion (AIC) in MEGA 6.0 was JC for ITS4 and
MaSC-1 (Tamura et al. 2013). Sequences of Favia fragum (JX452177.1,
JX452166.1, GQ 152790.1) and Favia pallida (JF785617.1) available in the GenBank
database were used as outgroup to root the trees because of the phylogenetic
proximity with Mussismilia (Schwartz et al. 2012). A time-calibrated phylogenetic
tree was inferred for both markers separately, using a previous mutation rate found in
the literature (0.004 for ITS – Savard et al. 1993; 6.77E-4 for MaSC-1 - Schwartz et al.
2012). We also used information from fossil records of the genus Mussismilia and of
the outgroups F. pallida and F. fragum that first appeared in the paleontological basin
around 23.03, 20.43 and 5.33 Ma bp respectively (Chevalier 1961, Perrin et al.
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1998). We inferred parameters from a run of 200 million steps sampled every 10,000
steps. Convergence and effective sample sizes (ESS>200) were checked in Tracer
(Rambaut and Drummond 2009), and the first 2000 trees were discarded as burned.
The program Figtree 1.4.2 was used to draw the resulting MCC tree (Rambaut 2009).
Demographic analysis
Historical demographic processes were inferred using neutrality tests Tajima‘s
D (Tajima 1989), Fu‘s Fs (Fu 1997) and mismatch distribution analysis (Harpeding
1994) for markers and each location in Arlequin v. 3.5. We also estimated posterior
distributions of population size (Ne) through the time for both markers separately
using the Extended Bayesian Skyline Plot analysis (EBSP) implemented in Beast v.
1.7. (Drummond and Rambaut 2007). We used the same substitution model and
mutation rate as for phylogenetic analysis. Runs of 200 million interactions were
conducted with samples being taken every 10,000 generations.
Results
All the obtained models presented high values of TSS and consequently,
high accuracy (Supplementary information 3). We observed a clear difference
between Mussismilia braziliensis distribution from present and Last Glacial Maximum
(LGM) (Figure 1). The models from current climate scenario (0 k – Figure 1) pointed
that M. braziliensis is potentially restricted to the Eastern region of the Brazilian coast
(10° to 20°S). In turn, the paleoclimatic models for LGM indicated a great reduction in
the potential distribution of the species (21 k before today – Figure 1). According to
this paleoclimatic model, during LGM, the continental shelf where reefs occur today
was exposed to the atmosphere and M. braziliensis were potentially restricted to
small areas near this region.
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Figure 1. Modeled distributions of Mussismilia braziliensis for present (0k) and LGM (21k) scenarios. In the left figure (0k), the continental shelf is submerged. In the right figure (21k), the continental shelf is exposed and represented by a gray band along the coast. Suitability means how suitable the environment is for the occurrence; the values are based on an ensemble of the five used algorithms Bioclim, Mahalanobis, Domain-Gower, SVM and MaxEnt.
Genetic diversity, haplotype networks and population structure
Sequences of ITS presented 619 bp, and MaSC-1 presented 274 bp with 6
and 5 polymorphic sites, respectively, and no gaps (Table 1). Both markers showed
ambiguous peaks and, because of this, we applied haplotype reconstruction
conducted in PHASE. The analysis resulted in 8 solved sequences for ITS and 9 for
MaSC-1 with posterior probability higher than 0.9. Sequences of SRP54 presented
358 bp; however, they were monomorphic.
The haplotype and nucleotide diversity is described in Table 1. The ITS
marker showed higher molecular diversity when compared to MaSC-1; however, no
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geographic structure was observed in both markers. The ITS network indicated a
wide dispersion of haplotypes among localities with few exclusive haplotypes in each
locality (Figure 2). Regarding the MaSC-1 network, it presented low variation with two
common haplotypes widely distributed along sampled places and presented few
mutational steps between groups indicated by BAPS (Figure 2).
Pairwise FST values were not significant among localities when we analyzed
ITS, but showed some significant differentiation between P. Abrolhos and other
places when MaSC-1 was observed (Table 2). Isolation-by-distance (IBD) was not
detected for both markers (Figure 4). The AMOVA showed that the highest
percentage of genetic variation for both markers is within populations, with ~82% for
ITS and ~94% for MaSC-1 (Table 3).
Phylogenetic inference and divergence time
Phylogenetic Bayesian inference for ITS and MaSC-1 did not recover the
same topology, and they presented low posterior probability nodes along the
terminals (Figure 5). The groups indicated by BAPS for MaSC-1 were not recovered
in phylogeny. Time calibrated analysis using ITS and MaSC-1 presented different
mean values, but they occurred in the same confidence interval (Figure 5).
Divergence time from the outgroup occurs in 31.52 Ma (95% highest posterior
density ‗HPD‘ = 18.48-79.92 Ma – Figure 5) for ITS and 23.17 Ma (95% HPD =
19.51–41.01 Ma – Figure 5) for MaSC-1, while the species diversification occurred in
4.62 Ma (95% HPD 0.54-18.04Ma – Figure 5) and 9.13 Ma (95% HPD 2.8 – 17.7 Ma
– Figure 5) for ITS and MaSC-1, respectively.
Demographic analysis
Fu‘s FS detected demographic expansion in ITS for the most distant localities,
Itacimirim and P. Abrolhos and for total data (Table 1). However, the other analysis
did not detect any historical demographic fluctuations (Table 1 - Figure 7).
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Table 1. Diversity indices and neutrality tests for Mussismilia braziliensis. N = nº of individuals; S = nº of polymorphic sites;
H = nº of haplotypes; Hd = haplotype diversity; π = nucleotide diversity; s.d. = standard deviation; * = statistically
significant values (p<0.05).
Table 2. Population pairwise ΦST for Mussismilia braziliensis. ITS is below and MaSC-1 is above the diagonal.
Table 3. Hierarchical analysis of molecular variance (AMOVA) was used to estimate levels of genetic differentiation among populations (FST), between groups of populations or regions (FCT) and between populations within regions (FSC).
ITS MaSC-1
Location N S H Hd (s.d.) π (s.d.) D FS N S H Hd (s.d.) π (s.d.) D FS
Itacimirim 4 4 6 0.89 (0.11) 0.003 (0.002) 0.9 -2.8* 6 5 3 0.53 (0.14) 0.006 (0.005) 0.32 2.03
Caramuanas 5 3 5 0.87 (0.07) 0.002 (0.001) 1.0 -1.5 5 5 3 0.51 (0.16) 0.005 (0.004) -0.33 1.48
P. Seguro 2 3 4 1(0.18) 0.003 (0.002) 0.2 -2.2 4 4 5 0.86 (0.11) 0.008 (0.005) 1.59 -1.04
P. Leste - - - - - - - 2 4 3 0.83 (0.22) 0.008 (0.007) -0.07 0.25
P. Abrolhos 7 5 9 0.95 (0.04) 0.003 (0.002) 1.5 -4.4* 7 0 1 0 0 0 0
Total 18 6 13 0.9 (0.02) 0.003 (0.002) 0.8 -6.3* 24 5 6 0.49 (0.08) 0.006 (0.004) 0.94 0.27
Itacimirim Caramuanas P. Seguro P. Leste P. Abrolhos
Itacimirim -0.09373 0.03633 0.21197 0.18933*
Caramuanas -0.03 0.0833 0.28469 0.14563
P. Seguro 0.16 0.13 -0.10121 0.54424*
P. Leste - - - 0.82170*
P. Abrolhos 0.02 0.05 0.02 -
ITS MaSC-1
Source of variation d.f. Sum of squares
Variance components
Percentage of variation
d.f. Sum of squares
Variance components
Percentage of variation
Groups 2 3.222 0.09683 Va 9.86 2 2.783 -0.13786 Va -17.47
Population within groups 1 0.567 -0.04031 Vb -4.11 2 6.084 0.27954 Vb 35.42
Within population 32 29.600 0.92500 Vc 94.24 43 21.708 0.64748 Vc 82.05
Total 35 33.389 0.98151 47 36.708 0.78916
Fixation indexes: FSC: -0.04557; FST: 0.05758; FCT: 0.09865
FSC: 0.30155; FST: 0.17953; FCT: -0.17469
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ITS MaSC-1
A B
Figure 2. Median joining haplotype network for both markers. Colors represent sampling localities for ITS and groups inferred by BAPS for MasSC-1. Circle sizes represent haplotype frequencies.
Figure 3. Pie chart indicating the diversity distribution along sampling points. (A) Frequency of haplotypes of ITS (B) Frequency of genetic groups indicated by BAPS for MaSC-1.
Figure 4. Mantel test for Mussismilia braziliensis using ITS and MaSC-1. The R² and p-value of each analysis are indicated on the graph.
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Figure 5. Bayesian phylogenetic inference for ITS and MaSC-1 sequences. The
divergence times of the main nodes are shown, with 95% HPD in parentheses.
Posterior probabilities > 0.9 are indicated in black squares.
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Figure 6. The demographic analysis Extended Bayesian Skyline Plot for Mussismilia braziliensis for ITS and MaSC1, with the median shown in the black line and the 95% HPD interval shown in the gray line.
Discussion
Paleoclimatic modeling
Our ENM models indicate a reduction of Mussismilia braziliensis potential
distribution from the present (0k) to LGM (21k) and suggest that this species was
restricted to a small area along the coast during glaciation times. The models are in
accordance with the hypothesis of refugia near the Abrolhos region (Leão 1983);
however, contrary to what was expected by this author, at least in LGM, the predicted
stable regions were not located in the Victoria-Trindade mountain chain, but in
northern regions near to the coast and seamounts of Minerva, Rodgers and Hotspur.
This results are unexpected since regions near to the coast are usually more
subject to sedimentation than more distant regions, and we expected that seamounts
away from the coast would have been more favorable to reef growth (Dutra et al.
2006, Leão e Kikuchi 2005). This hypothesis has been supported in the case of some
species (Pinheiro et al. 2017, Peluso et al. 2018). However, some geological studies
have described the occurrence of deep biogenic structures on the slopes of the
continental shelf that probably were formed during punctuated sea level rises since
the LGM (Droxler and Jorry 2013, Khanna et al. 2017). Some species may have been
able to occur at these sites. In Brazil, (Kikuchi and Leão 1998) reported evidences of
biogenic structures in oceanic slopes at a depth of around 80 m; other biogenic
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structures were also reported in deep sectors to the north of Abrolhos Bank (Bastos
et al. 2013, Bastos et al. 2016). Further studies with a detailed description of these
areas can help to understand the formation of the current diversity in this region.
Another interesting pattern is that the latitudinal amplitude of occurrence of the
species presented very little, but interesting, variation. From LGM to the present, M.
braziliensis apparently expanded its potential distribution slightly to the south.
According to the environmental layers used in this study (Supplementary information
2), the annual temperature variation around Abrolhos Bank
18°40'59.49"S/38°59'33.94"W decreased from LGM to the present. High variations in
the temperature can prejudice the metabolism of many species (Sheppard et al.
2009), and this could perhaps explain the low suitability of M. braziliensis in the south
of Abrolhos bank in LGM. The other environmental characteristics around the coast
of Bahia are apparently very peculiar, and this condition did not shift much along the
latitudinal gradient during the time period studied.
Genetic diversity and population structure
Each marker studied presented very different diversity. The absence of
variation found for Srp54 is in agreement with a possible demographic reduction of
this species, whereas this marker has shown itself to be quite variable for other coral
species (Frade et al. 2010, Concepcion et al. 2008). On the other hand, ITS and
MaSC-1 presented the common diversity observed for these markers in corals
(Saavedra-Sotelo et al. 2011, Goodbody-Gringley et al. 2012, Schwartz et al. 2012).
The low population structure, the indication that a major part of variation is
within localities (Table 1 and 3) and the absence of isolation-by-distance do not
corroborate the hypothesis of colonization from Pleistocene refugia in submerged
seamounts near Abrolhos Bank (Leão 1983). However, it can be suggested that the
hypothesized refugia did not change the latitudinal amplitude of geographical
occurrence over geological time. These data are also in agreement with our ENM
results, which indicated a reduction in the area of potential distribution, but not in
latitudinal amplitude. As discussed before, the possibility of occurrence of coral
species along the coast and not restricted to small refugia from LGM cannot be
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rejected, and studies to identify these structures should be carried out, in order to
better understand the formation of current coral diversity.
The low genetic structuring observed can also be justified by traits related to
the life history of Mussismilia braziliensis. This species has annual and synchronic
reproductive cycles and a broadcast behavior with spawning happening around
March and May (Pires et al. 1999). In this pattern, gametic fertilization occurs in the
water column, and the larva is exposed to dispersion by marine currents for more
time. Consequently, this reproductive pattern is known for its wide dispersion and
connectivity among populations (Veron 1995), although it does not always occur
(Ayre and Hughes 2000, Miller and Ayre 2008). Then, this reproductive behavior
could also be an alternative explanation to the few structure observer for M.
braziliensis.
The two groups indicated by BAPS for MaSC-1, found with a low difference
between then, could indicate the presence of two distinct areas that remained
isolated for a short time and from where our sampled banks received immigrants.
This disruption probably occurred before the LGM because the Paleoclimatic model
(Figure 1) does not indicate the existence of two isolated refugia. Since these groups
occur sympatrically and have no geographic correspondence, it is difficult to estimate
the possible location of these previous refugia.
Phylogenetic inference and divergence time
The absence of different lineages within Mussismilia braziliensis highlights the
low genetic structure in this group. Values of divergence time between this species
and the outgroup along the Oligocene-Miocene evidenced by both markers (Figure 7)
agree with their phylogenetic distance, since we are dealing with different genera.
Further studies should include a closer group to estimate a more precise time of
emergence for this specie. Concerning the time of diversification estimated during the
Mio-Pliocene (Figure 7), other studies also found similar results for closer groups of
Mussismilia. Schwartz et al. (2012) revealed that all components of the live
Caribbean ‗‘Faviids‘‘, recently classified as a sister group of the genus Mussismilia
(Schwartz et al. 2012), have a time of diversification close to that of our data,
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occurring from 4.66 Mya (95% HPD = 3.01 - 7.06 Ma) to 8.21 Mya (95% HPD = 8.77-
20.09 Ma).
According to Schwartz et al. (2012), environmental changes that occurred
from the Miocene to Pliocene, such as total closure of the Isthmus of Panamá, the
decrease in sea level depth, primary productivity and turbidity in water and an
increase in salinity and temperature (Mcneill et al. 2001, Jain and Collins 2007),
favored a turnover of coral fauna and probably led to the diversification of ‗Faviids‘.
Klaus et al. (2011, 2012) suggest that these changes led to the substitution of more
heterotrophic species with bigger polyps and large tentacles by a more autotrophic
species with small polyps. The polyps with intermediary sizes (8 to 10 mm in
diameter – Budd et al. 2012) and the relatively high resistance to sedimentation of
Mussismilia braziliensis (Loiola et al. 2013) indicate that its emergence during the
Mio-Pliocene is probable. Fossils of this species were not registered during this
period. However, this absence of records may be due in part to its similarity to and
misidentification with other Caribbean groups to which the species has traditionally
been assigned (e.g. Acanthastraea braziliensis Verrill, 1868).
Demographic analysis
Our analysis did not find signals of demographic fluctuation or a bottleneck
during the Pleistocene. Although the results indicated that the potential area for
occupancy by this species has increased from LGM to the present day (Figure 1), it
may be possible that its effective population size has not increased significantly. A
previous study carried out with polychaets of the genus Phragmatopoma, a sessile
organism as corals, shows that this species increased its population since 0.2 Ma
rather than since the LGM, but further discussion was not provided by the author.
Probably, Pleistocene glacial cycles affected this species long before the Last Glacial
Maximum.
Conclusion
Coupling different techniques to study the evolutionary history of the endemic
coral species Mussismilia braziliensis revealed interesting information. ENM
predictions indicate that this species have its distribution area reduced during LGM,
but maintained approximately the same latitudinal amplitude. Differently to what was
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hypothesized, the spatial region of refugia does not include the Vitória-Trindade
Seamount Chain, but regions to the north of Abrolhos Bank. The genetic data show
low structure, and it was not possible to identify ancient lineages or more diverse
regions. However, these results is consistent with the probable few changes in the
latitudinal amplitude of occurrence over geological time. The inclusion of other
ancient paleo scenarios in ENM analysis and the use of more advanced molecular
techniques will certainly develop the understanding of this kind of study. The
comprehension of the evolutionary history of coral species and their population
behavior during glacial cycles has an important application in helping recent concerns
about the influence of climate change on the future of coral reef ecosystems.
Acknowledgements
We are very grateful to Prof. Dr. Ruy K. P. Kikuchi (Laboratório de Recifes
de Corais e Mudanças Globais – RECOR) for help with logistical and financial
support for Abrolhos fieldwork. We thank colleagues from the Laboratório de
Diversidade Genética – UNICAMP, Fernanda Fontes, Cecília Fiorini, Jair Mendes,
Luiz Bartoleti, Thadeu Sobral-Souza, Priscila Madi, Felipe Roberto, Beatriz Pereira,
Lívia Zuffo, Gustavo Pugliese, Wendy Arroyo and João Claudio, for help with
suggestions and discussions. We thank Prof. Dr. Cláudio Sampaio (Universidade
Federal de Alagoas), Prof. Dr. Igor Cruz (Universidade Federal da Bahia), José de
Anchieta, Ricardo Miranda, Miguel Loiola, Lua Porto, Thiago Albuquerque, Adriano
Leite and José Amorim, for outstanding help in the fieldwork. We also acknowledge
the following entities for financial support: Coordenação de Aperfeiçoamento de
Pessoal de Nível Superior for a research grant; Conselho Nacional de
Desenvolvimento Científico e Tecnológico - CNPq (311763-2014-6); São Paulo
Research Foundation – FAPESP (201202526-7).
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Supplementary information
Supplementary information 1. Distribution of points used to paleoclimatic modeling.
Different colors indicates the data base from where points were collected.
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Supplementary information 2. Layers from present and from Last Glacial Maximum
used to ENM analysis. Bat = Bathymetry, Biogeo3 = Plan curvature, Biogeo4 =
Profile curvature, Biogeo8 = Mean annual SSS (psu), Biogeo11 = Annual range in
SSS (psu), Biogeo15 = SST of the warmest month (°C), Biogeo 16 = Annual range in
SST (°C).
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Supplementary information 3. Results of accuracy analisis ("thrs" ―Auc‖ and ―Tss‖) from ENM of Mussismilia braziliensis. BIOCLIN: "AUC" "TSS" "mbraziliensis1" 0.00116103 0.998012798438935 0.992424242424242 "mbraziliensis2" 0.00116103 0.999856519742883 0.996212121212121 "mbraziliensis3" 0.00115945 1 1 "mbraziliensis4" 0.00115945 0.996046491531282 0.988607558474479 "mbraziliensis5" 0.00116103 0.994318181818182 0.988636363636364 "mbraziliensis6" 0.00115945 0.999848772900104 0.996212121212121 "mbraziliensis7" 0.00494414 0.998063016528926 0.992424242424242 "mbraziliensis8" 0.00116103 1 1 "mbraziliensis9" 0.00116103 0.999849345730028 0.992424242424242 "mbraziliensis10" 0.00116103 0.999906737832874 0.996212121212121 "mbraziliensis11" 0.00116103 1 1 "mbraziliensis12" 0.00115945 0.994109344394515 0.984805277105657 "mbraziliensis13" 0.00115945 0.998098859315589 0.996197718631179 "mbraziliensis14" 0.00115945 0.996140108307409 0.988607558474479 "mbraziliensis15" 0.00116103 0.988492883379247 0.973484848484849 "mbraziliensis16" 0.00116103 0.996212121212121 0.992424242424242 "mbraziliensis17" 0.00116103 0.996212121212121 0.992424242424242 "mbraziliensis18" 0.00115945 0.998034047701348 0.9924098398433 "mbraziliensis19" 0.00116103 0.992044019742883 0.973484848484849 "mbraziliensis20" 0.00116103 0.998106060606061 0.996212121212121 GOWER: "thrs" "AUC" "TSS" "mbraziliensis1" 0.04519634 0.997905188246097 0.988636363636364 "mbraziliensis2" 0.04792018 0.999799127640037 0.988636363636364 "mbraziliensis3" 0.12478665 0.99994238967623 0.996212121212121 "mbraziliensis4" 0.12534081 0.999625532895495 0.988636363636364 "mbraziliensis5" 0.00998827 0.996169077134986 0.988636363636364 "mbraziliensis6" 0.04836348 0.999812766447747 0.992424242424242 "mbraziliensis7" 0.18963712 0.998019972451791 0.988636363636364 "mbraziliensis8" 0.04570076 1 1 "mbraziliensis9" 0.04539811 0.999770431588613 0.984848484848485 "mbraziliensis10" 0.04590252 0.999806301652893 0.984848484848485 "mbraziliensis11" 0.23555324 0.999928259871442 0.992424242424242 "mbraziliensis12" 0.00393023 0.999524714828897 0.988636363636364 "mbraziliensis13" 0.04609647 0.998098859315589 0.996197718631179 "mbraziliensis14" 0.40458514 0.997861216730038 0.981002995736836 "mbraziliensis15" 0.00473396 0.992079889807163 0.973484848484849 "mbraziliensis16" 0.04454061 0.998027146464647 0.992424242424242 "mbraziliensis17" 0.007214 0.997905188246097 0.988636363636364 "mbraziliensis18" 0.04508892 0.998005242539463 0.9924098398433
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"mbraziliensis19" 0.04630605 0.999540863177227 0.981060606060606 "mbraziliensis20" 0.19224177 0.999885215794307 0.996212121212121 MAHALANOBIS DISTANCE: "thrs" "AUC" "TSS" "mbraziliensis1" -531.7225601 0.999928259871442 0.996212121212121 "mbraziliensis2" -24.73529131 0.999971303948577 0.996212121212121 "mbraziliensis3" -310.29564233 0.999971194838115 0.996212121212121 "mbraziliensis4" -37.68346414 0.999913584514345 0.992395437262358 "mbraziliensis5" -515.88622709 0.999942607897153 0.996212121212121 "mbraziliensis6" -16.93521875 1 1 "mbraziliensis7" -79.51551902 0.999942607897153 0.992424242424242 "mbraziliensis8" -178.64442806 1 1 "mbraziliensis9" -17.93913149 1 1 "mbraziliensis10" -81.4604323 0.999928259871442 0.992424242424242 "mbraziliensis11" -78.96134254 1 1 "mbraziliensis12" -451.8932715 0.999841571609632 0.988636363636364 "mbraziliensis13" -409.1617331 0.999971194838115 0.996212121212121 "mbraziliensis14" -23.16027289 0.999913584514345 0.992395437262358 "mbraziliensis15" -721.06207997 0.999727387511478 0.984848484848485 "mbraziliensis16" -399.00270271 1 1 "mbraziliensis17" -554.82575819 0.999942607897153 0.992424242424242 "mbraziliensis18" -356.69266907 0.999956792257172 0.996212121212121 "mbraziliensis19" -234.78952741 0.99974173553719 0.981060606060606 "mbraziliensis20" -172.52677939 0.999985651974288 0.996212121212121 MAXENT: "thrs" "AUC" "TSS" "mbraziliensis1" 0.13953881 0.999870867768595 0.992424242424242 "mbraziliensis2" 0.12046651 0.99982782369146 0.988636363636364 "mbraziliensis3" 0.27923979 0.999971194838115 0.996212121212121 "mbraziliensis4" 0.29784517 0.99982716902869 0.988636363636364 "mbraziliensis5" 0.15427654 0.999956955922865 0.996212121212121 "mbraziliensis6" 0.14565508 0.999913584514345 0.992424242424242 "mbraziliensis7" 0.47641416 0.99991391184573 0.992424242424242 "mbraziliensis8" 0.14222172 1 1 "mbraziliensis9" 0.13439813 0.999799127640037 0.981060606060606 "mbraziliensis10" 0.3817455 0.999813475665748 0.984848484848485 "mbraziliensis11" 0.32066466 0.999956955922865 0.996212121212121 "mbraziliensis12" 0.11372984 0.999409494181357 0.988636363636364 "mbraziliensis13" 0.17978071 0.999971194838115 0.996212121212121 "mbraziliensis14" 0.29884647 0.99982716902869 0.984848484848485 "mbraziliensis15" 0.08983454 0.999669995408632 0.981060606060606 "mbraziliensis16" 0.1370171 0.999985651974288 0.996212121212121 "mbraziliensis17" 0.12651266 0.999842171717172 0.992424242424242 "mbraziliensis18" 0.14769015 0.999956792257172 0.996212121212121 "mbraziliensis19" 0.4371769 0.999727387511478 0.984848484848485 "mbraziliensis20" 0.26950105 0.999842171717172 0.992424242424242
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SVM: "thrs" "AUC" "TSS" "mbraziliensis1" 0.07645898 0.99110422405877 0.981060606060606 "mbraziliensis2" 0.19223104 0.999856519742883 0.988636363636364 "mbraziliensis3" 0.07182758 0.992784306947805 0.980988593155893 "mbraziliensis4" 0.43117132 0.996456965088144 0.988593155893536 "mbraziliensis5" 0.07060053 0.992825987144169 0.981060606060606 "mbraziliensis6" 0.07329922 0.998163670929831 0.984805277105657 "mbraziliensis7" 0.5782517 0.997403007346189 0.992424242424242 "mbraziliensis8" 0.67311189 1 1 "mbraziliensis9" 0.84742829 0.992510330578512 0.992424242424242 "mbraziliensis10" 0.0730455 0.994655360422406 0.981060606060606 "mbraziliensis11" 0.07294915 0.998242366850321 0.988636363636364 "mbraziliensis12" 0.16562407 0.999668740638322 0.984848484848485 "mbraziliensis13" 0.09155916 0.999985597419057 0.996197718631179 "mbraziliensis14" 0.39746485 0.996111303145524 0.984834082267542 "mbraziliensis15" 0.06389037 0.998593893480257 0.981060606060606 "mbraziliensis16" 0.28138316 0.989081152433425 0.984848484848485 "mbraziliensis17" 0.34373125 0.999038682277319 0.992424242424242 "mbraziliensis18" 0.12996425 0.99994238967623 0.9924098398433 "mbraziliensis19" 0.07035221 0.990881829660239 0.973484848484849 "mbraziliensis20" 0.303383 0.996470385674931 0.988636363636364
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DISCUSSÃO GERAL
Diversidade, inferência filogenética e tempos de divergência do “Complexo
Siderastrea” e da espécie endêmica Mussismilia braziliensis.
Este trabalho trouxe informações importantes sobre a diversidade e história
evolutiva de dois grupos de corais que estão entre os principais construtores dos
recifes brasileiros. As espécies do gênero Siderastrea e a Mussismilia braziliensis
apresentaram diversidade haplotípica alta e diversidade nucleotídica baixa, um
padrão comum encontrado para outras espécies de coral (Nunes et al. 2011, Nunes
et al. 2009). Destaca-se que este trabalho fornece os primeiros dados sobre a
diversidade genética de M. braziliensis, que apesar de ser uma espécie endêmica e
de distribuição restrita, é ainda pouco estudada. Em relação ao gênero Siderastrea,
as análises indicam que os indivíduos brasileiros são muito semelhantes
geneticamente às espécies do caribe S. radians e S. siderea e que a espécie S.
stellata, considerada endêmica para o Brasil (Leão et al. 2003), pode constituir em
uma variação morfológica da espécie S. siderea. Estes resultados chamam a
atenção para a necessidade de uma revisão do gênero considerando a proximidade
filogenética entre S. stellata e S. siderea e não entre S. stellata e S. radians, como
havia sido sugerido por outros trabalhos (Forsman et al. 2005), e a necessidade de
se realizar análises comparativas genéticas e morfológicas considerando uma ampla
amostragem no Oceano Atlântico.
Os resultados de tempo de divergência mostraram que os períodos de
diversificação observados coincidem com períodos de grandes mudanças
ambientais no Oceano Atlântico. A divergência de ~29.02 Ma apontada entre S.
radians e S. siderea pode estar relacionada à intensificação das correntes e
diminuição da temperatura da água no Atlântico Central entre o Oligoceno/Mioceno
devido ao fechamento da conexão entre o Mar de Tethys e o Atlântico, à abertura do
canal de Drake no Oceano Antártico (Smart and Murray 1994, Edinger and Risk
1995, Nisancioglu 2003) e à variações do nível do mar no período (Rossetti et al.
2013). Já, a diversificação de M. braziliensis entre o final do Mioceno e o início do
Plioceno pode estar relacionada a diminuição do nível do mar, redução da
produtividade e da turbidez da água e ao aumento da temperatura e salinidade na
região (Mcneill et al. 2001, Jain and Collins 2007). De acordo com Schwartz et al.
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(2012), este período foi de grande importância para diversificação de outros grupos
da Família Faviidae a qual M. braziliensis pertence. Certamente, mais estudos são
necessários para apoiar estas hipóteses, entretanto, as análises realizadas
representam um passo importante para o entendimento da história evolutiva destes
grupos.
Processos históricos responsáveis pela diversidade de corais na costa do
Brasil
Embora as espécies do gênero Siderastrea e a espécie M. braziliensis
possuam características biológicas e distribuições geográficas bastante diferentes,
os resultados indicaram respostas semelhantes às variações ambientais ao longo do
tempo geológico na costa do Brasil. As análises de diversidade genética, inferência
filogenética e demografia não mostraram os sinais de colonização recente a partir
do Caribe como foi proposto por Leão et al. (2003), e nem a partir de refúgios
pleistocênicos em regiões de cadeias montanhosas próximas ao banco de abrolhos
como sugerido por (Leão 1983); também não mostram expansão recente, indicando
que as populações podem ter resistido a variações no nível do mar no Pleistoceno e
mantido a sua amplitude de distribuição latitudinal. A simulação paleoclimática
baseada em modelagem de nicho realizada para M. braziliensis também apontou
para a manutenção na extensão latitudinal ocupada por essa espécie ao longo da
costa durante o último máximo glacial.
Este resultado sugere que a costa do Brasil pode ter permanecido
relativamente estável ao longo do tempo geológico em relação a outras regiões no
Atlântico e, apesar de ser uma região marginal, mantido condições para o
desenvolvimento de recifes. A discussão sobre a presença de uma fauna arcaica
com características do terciário representada principalmente pelo gênero endêmico
Mussismilia, que foi amplamente distribuído no Oceano Atlântico no passado, sugere
que esta região seja uma área de sobrevivência para este gênero provavelmente
devido a essa estabilidade (Leão 1983, Leão and Kikuchi 2005, Nunes et al. 2008).
Trabalhos na literatura mostram que o Caribe sofreu grandes modificações
geotectônicas como o fechamento do Istmo do Panamá e modificações na
circulação (Edinger and Risk 1995, Nisancioglu 2003, O'Dea et al. 2016). Depósitos
paleontológicos de recifes fósseis nesta região registram períodos de grandes
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extinções seguidas de diversificações associados a esses eventos (Budd 2000a).
Embora os dados obtidos tenham apontado para um cenário de maior estabilidade
ambiental no Brasil, mais investigações são necessárias para avaliar a sua
abrangência para a fauna de corais construtores brasileiros como um todo.
Outro padrão biogeográfico que foi aqui corroborado é a barreira na região
entre 8 e 10º de latitude, encontrada para o gênero Siderastrea. Esta quebra já havia
sido encontrada para este grupo em um trabalho com isoenzimas (Neves et al.
2008), e para outros grupos marinhos (Souza et al. 2017, Picciani et al. 2017). Em
geral, tem sido atribuído ao desague do rio São Francisco e ao giro subtropical do
Atlântico Sul que chega ao Brasil nessa região e bifurca para o sul formando a
Corrente do Brasil e para o norte formando a Corrente Norte do Brasil (Carvalho and
Kikuchi 2013). É uma quebra que provavelmente não foi responsável pela origem de
S. radians e S. siderea uma vez que as espécies provavelmente divergiram muito
antes, como mostrado pelas análises de tempo de divergência, entretanto, limita sua
distribuição e sugere uma diferenciação de nicho entre elas. A espécie M.
braziliensis parece também estar sujeita a essa barreira uma vez que ela
aparentemente restringe a sua distribuição a norte. Contudo, esta espécie parece
também estar limitada a sul por uma quebra na região do Rio Doce, também
observada para outras espécies (Picciani et al. 2017). A presença dessas quebras
reforça a ideia de que a região de ocorrência de recifes na costa brasileira não é
uma única unidade biogeográfica. Como indicado por Leão et al. (2003), ela
apresenta quebras que precisam ser consideradas em futuros trabalhos filogenéticos
e filogeográficos.
Por fim, destaca-se o a importância deste trabalho em tentar entender os
processos biogeográficos históricos responsáveis pela distribuição da biodiversidade
atual de corais escleractíneos da costa do Brasil. Trata-se também de um trabalho
pioneiro por associar abordagens filogeográficas baseadas em análises de
coalescência e simulações paleoclimáticas baseadas em modelagem de nicho para
acessar estes processos.
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CONCLUSÕES GERAIS
As análises filogeográficas para os dois grupos estudados, o gênero
Siderastrea e a espécie Mussimsilia braziliensis, não mostraram sinais de
colonização recente a partir do Caribe ou a partir de refúgios pleistocênicos
em regiões de cadeias montanhosas próximas ao Banco de Abrolhos,
indicando que elas podem ter resistido a variações no nível do mar desde o
Último Máximo Glacial e mantido a sua amplitude de distribuição latitudinal
até o presente.
Os resultados de tempo de divergência indicaram que mudanças ambientais
que ocorreram entre o Oligoceno/Mioceno e entre o Mioceno/Plioceno foram
importantes para a diversificação dos grupos estudados.
Os dados obtidos apoiam a presença de uma barreira biogeográfica na região
entre as latitudes 8 e 10º, padrão que tem sido discutido na literatura.
A associação entre análises filogenéticas e morfológicas do gênero
Siderastrea indicaram a necessidade de realização de uma revisão
taxonômica do grupo, levando em consideração a proximidade entre S.
siderea e S. stellata e a uma ampla amostragem no Oceano Atlântico.
As simulações paleoclimáticas para a espécie M. braziliensis apoiaram os
resultados obtidos pelos dados genéticos uma vez que indicaram que embora
a distribuição potencial desta espécie tenha reduzido no Último Máximo
Glacial, a sua amplitude latitudinal de ocorrência se manteve.
A integração de diferentes metodologias, análises filogeográficas,
informações morfológicas e modelagem de distribuição, se mostrou uma boa
abordagem para estudar os processos históricos responsáveis pela
distribuição da biodiversidade de corais escleractíneos na costa brasileira.
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